Tactile touch screen

ABSTRACT

A machine ( 10 ) is operative to carry out financial transfers responsive to data included on data bearing records including user cards. The machine includes a user interface ( 15 ) including a display ( 24 ). The user interface includes a card reader ( 16 ) which is operative to read data on user cards which identify at least one of user and a users financial accounts. Records of the financial transfers are provided by a printer ( 30 ). A touch screen display module ( 608 ) is operative to securely receive manual inputs and/or card data. The touch screen display module includes a contact surface that can be electronically contoured to provide outputs that can be perceived through finger contact with the contact surface.

This application is a continuation of U.S. application Ser. No.14/070,696 filed on Nov. 4, 2013 that is a continuation of U.S.application Ser. No. 13/134,654 filed Mar. 14, 2012, now U.S. Pat. No.8,573,479, that claims benefit pursuant to 35 U.S.C. §119(e) ofProvisional Application 61/354,778 filed Jun. 15, 2010. The disclosuresof each of the aforementioned applications are incorporated herein byreference in their entirety.

TECHNICAL FIELD

This disclosure relates to a touch screen user interface.

BACKGROUND

Automated banking machines may include a card reader that operates toread data from a bearer record such as a user card. The automatedbanking machine may operate to cause the data read from the card to becompared with other computer stored data related to the bearer. Themachine operates in response to the comparison determining that thebearer record corresponds to an authorized system user or account datato carry out at least one transaction which is operative to transfervalue to or from at least one account. A record of the transaction isalso commonly printed through operation of the automated banking machineand provided to the user. A common type of automated banking machineused by consumers is an automated teller machine which enables customersto carry out banking transactions. Banking transactions carried out mayinclude the dispensing of cash, the making of deposits, the transfer offunds between accounts and account balance inquiries. The types ofbanking transactions a customer can carry out are determined by thecapabilities of the particular banking machine and the programming ofthe institution operating the machine.

Other types of automated banking machines may be operated by merchantsto carry out commercial transactions. These transactions may include,for example, the acceptance of deposit bags, the receipt of checks orother financial instruments, the dispensing of rolled coin or othertransactions required by merchants. Still other types of automatedbanking machines may be used by service providers in a transactionenvironment such as at a bank to carry out financial transactions. Suchtransactions may include for example, the counting and storage ofcurrency notes or other financial instrument sheets, the dispensing ofnotes or other sheets, the imaging of checks or other financialinstruments, and other types of service provider transactions. Forpurposes of this disclosure an automated banking machine, automatedtransaction machine or an ATM shall be deemed to include any machinethat may be used to electronically carry out transactions involvingtransfers of value.

Automated banking machines may benefit from improvements.

OVERVIEW OF EXAMPLE EMBODIMENTS

Described in an example embodiment herein is touch screen display thatselectively output visual elements on the display, the visual elementsare visible on the display through a contact surface of the touch screenthat has at least one contact area that is manually touchable. Thevisual elements include a first visual element. The first visual elementis visible through a first contact area. The first visual element isselectable by a user of the display through manual contact with thefirst contact area. Data representative of a manual touch with the firstcontact area corresponding to a user selection of the first visualelement from the touch screen is received, wherein the first visualelement is associated with tactile output. The touch screen selectivelyproduces tactile output by causing at least one change in contour of thefirst contact area that is independent of any manual contact with thefirst contact area, responsive at least in part to an appearance ofvisual indicia in the first contact area, and selectively producetactile output through the first contact area which allows the user totangibly feel, through manual contact with the first contact area asensation of movement from the first contact area.

Described in an example embodiment herein is a touch screen that outputsvisual elements that are visible through a contact surface on the touchscreen. The contact surface includes a first contact area. The contactsurface includes a changeable contour that allows the touch screen toselectively provide tactile output through the first contact area. Thetouch screen provides tactile output that is tangibly indicative of afirst element which is user selectable through manual contact with thefirst contact area through the first contact area prior to manualcontact with the first contact area during the user session. The tactileoutput provided through the first contact area is caused by at least onechange in the contour of the first contact area. Data representative ofmanual contact with the first contact area corresponding to a userselection of the first element is received.

Described in an example embodiment herein is a touch screen that outputsvisual elements that are visible through a contact surface of a touchscreen associated with a touch screen display. The contact surfaceincludes a first contact area. The contact surface includes a changeablecontour that allows the touch screen to selectively provide tactileoutput through the first contact area. The first contact area if thetouch screen temporarily provides tactile output through the firstcontact area independent of any manual contact with the first contactarea. The tactile output provided through the first contact area iscaused by at least one change in the contour of the first contact area.The tactile output provided through the first contact area is tangiblyindicative of a first element which is user selectable through manualcontact with the first contact area. Data representative of manualcontact with the first contact area, which corresponds to a userselection of the first element is received.

Other example embodiments include computer readable medium ofinstructions and methods for implementing the aforementioned touchscreens.

Further aspects of the exemplary embodiments will be made apparent inthe following detailed description. It should be understood that thefeatures described are exemplary and in other embodiments otherapproaches may be used which nonetheless employ the features as claimedherein.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a front plan view of a fascia of an exemplary automatedbanking machine.

FIG. 2 is a schematic side view of components within a housing of thebanking machine shown in FIG. 1.

FIG. 3 is a further schematic side view of components within the housingof the banking machine shown in FIG. 1.

FIG. 4 is a view of a sheet stacking mechanism which may be employed inan exemplary embodiment of the banking machine.

FIG. 5 is a further view of the exemplary sheet stacking mechanism whichmay be used to hold multiple types of sheets.

FIG. 6 is a rear view of the housing of the automated banking machine ofthe exemplary embodiment.

FIG. 7 is a schematic view of an exemplary embodiment of a mechanism forseparating sheets from a stack of financial instrument sheets placedwithin the automated banking machine.

FIG. 8 is a front plan view of an exemplary picking member incombination with a plurality of non-contacting stripper rolls and acontacting stripper roll used for separating individual sheets from thestack.

FIG. 9 is a schematic view showing separation of a first sheet from asheet stack 5 through operation of the mechanism shown in FIG. 7.

FIG. 10 is a view showing a cross-sectional wave configuration impartedto a sheet through action of the picking member and the non-contactingstripper rolls.

FIG. 11 is a schematic view showing a cash acceptor mechanism moved to aservicing position and exposing the cash accepting opening in an upperportion of the chest of the automated banking machine.

FIG. 12 is a schematic view of the cash acceptor mechanism withdrawn forservicing similar to FIG. 11 and with a first embodiment of an accessdoor in an open position for purposes of accessing unacceptable sheetswhich have been identified through operation of the cash acceptormechanism

FIG. 13 is a view of the automated banking machine similar to FIG. 12but with an alternative access mechanism for accessing unacceptablesheets.

FIG. 14 is yet another view of the automated banking machine similar toFIG. 12 showing a further alternative mechanism for accessingunacceptable sheets.

FIG. 15 is a schematic view of the cash acceptor mechanism with a firstform of service panel shown in an open position for purposes ofservicing.

FIG. 16 is a view of the cash acceptor mechanism similar to FIG. 15 butwith an alternative form of service panels shown in an accessibleposition.

FIG. 17 is a schematic cross-sectional view of a chute to and from whichstacks of sheets are received and removed through the fascia of themachine, and including devices for capturing and draining water whichmay enter the chute.

FIG. 18 is an external isometric view of the cash acceptor mechanismrepresented in FIG. 17 and including a schematic representation of thedrain used for passing water collected in the chute to the outside ofthe machine.

FIG. 19 is a schematic view representative of a sealing system used inan exemplary embodiment to minimize the risk of contaminants enteringthe machine through the opening in the machine fascia through which thechute extends in an operative position of the cash acceptor mechanism.

FIG. 20 is a transparent side view of an alternative form of a mechanismfor accepting and storing financial instrument sheets that have beenprocessed by the cash acceptor mechanism.

FIG. 21 is an isometric view of the financial instrument holdingcontainer shown in FIG. 20, moved outside the machine.

FIG. 22 is a schematic view of a light emitting device which is operatedto facilitate use of the machine by users.

FIG. 23 is an enlarged view of the light emitting device shown in FIG.22.

FIG. 24 is a schematic view of the light emitting diodes included in thelight emitting device.

FIG. 25 is a cross-sectional view of the flexible web which includes thediodes in the light emitting device.

FIG. 26 is an isometric view of the fascia shown in FIG. 1 andparticularly the mirrors thereon which facilitate a user viewing thearea adjacent to them when operating the machine.

FIG. 27 is a schematic top view indicating the area viewable by a useroperating the machine.

FIG. 28 is an isometric view of a fascia similar to that shown in FIG.26 showing a concealment device.

FIG. 29 is an isometric view of a concealment device shown as covering akeypad.

FIG. 30 is a cross-sectional view of a concealment device taken alongthe line 30-30 of FIG. 29.

FIG. 31 is a partial isometric view of a fascia showing a concealmentdevice in an uncovered position.

FIG. 32 is an isometric view of an alternative concealment device forpreventing viewing of inputs to an automated banking machine customerkeypad by unauthorized persons.

FIG. 33 is a top view of the embodiment of the concealment device shownin FIG. 32.

FIG. 34 is an isometric view of a portion of an automated bankingmachine user interface which includes an alternative device forobscuring the viewing of inputs to a customer keypad by unauthorizedpersons, the concealment device being shown in an open position.

FIG. 35 is an isometric view similar to FIG. 34 but with the panelmembers of the 5 alternative concealment device shown in a closedposition.

FIG. 36 is a top view of the automated banking machine fascia portionshown in FIG. 35 with the panels shown in a closed position.

FIG. 37 is an isometric view of a portion of a banking machine fasciaand an associated keypad cover.

FIG. 38 is an isometric view similar to FIG. 37 but with the keypadcover shown in fixed engagement with the fascia.

FIG. 39 is an isometric view similar to FIG. 32 but including analternative form of a keypad cover.

FIG. 40 is a schematic view of an alternative embodiment similar to thatshown in FIG. 34 but which includes panels that are movable by movementmechanisms so that the panels operate to restrict viewing of inputsthrough the keypad at appropriate times during transactions.

FIG. 41 is an isometric view of an alternative automated banking machineuser interface with an alternative concealment device comprised offlexible material positioned for installation on the user interface.

FIG. 42 is an isometric view similar to FIG. 41 with the alternativeconcealment device installed.

FIG. 43 is a top plan view of a portion of an automated banking machineuser interface including a flexible keypad cover that is collapsibleshown in an operative position in which digit access to all of the keysof the keypad are provided.

FIG. 44 is a top plan view of the keypad cover similar to FIG. 43 butwith the keypad cover in a collapsed position.

FIG. 45 is a schematic view of a keypad cover that is collapsibleincluding deformable members included therein.

FIG. 46 is a schematic view of a keypad cover that is collapsibleincluding fluid cavities therein.

FIG. 47 is a schematic view of a keypad included on a banking machinewhich includes encryption capabilities and a visual indicator on thebanking machine interface which is operative to indicate when userinputs are being encrypted.

FIG. 48 is a front plan view of an automated banking machine includingexemplary user manual contact points.

FIG. 49 is a view similar to FIG. 48 but including schematic views ofareas contacted by ultraviolet radiation.

FIG. 50 is a view showing an exemplary device for emitting ultravioletlight.

FIG. 51 is an isometric view demonstrating use of the device shown inFIG. 50 to contact manual contact points of an automated banking machinewith ultraviolet radiation.

FIG. 52 is a schematic view showing embodiments of an exemplary ATMincluding a secure touch screen display module.

FIG. 53 is a schematic view similar to FIG. 52 but including a secureinput device for providing secure communication between the terminalprocessor and the touch screen display module.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

Referring now to the drawings and particularly to FIG. 1, there is showntherein a front plan view of an automated banking machine which in theexemplary embodiment is an automated teller machine (“ATM”) 10. ATM 10is a through-the-wall type machine which includes a fascia 12. Fascia 12is accessible to users of the machine who are positioned externally ofthe wall 14. In some embodiments wall 14 may be an exterior buildingwall and ATM 10 may be one that is configured for use in a walk-up ordrive-up environment. In other embodiments the ATM may be used in anindoor environment. Of course this configuration is exemplary and inother embodiments, other types of ATM configurations may be used.

The exemplary ATM includes a user interface generally indicated 15. Theuser interface of the exemplary embodiment includes input devices forreceiving inputs from users. These input devices include a card reader16, a keypad 18, function keys 20 and an imaging device such as a camera22. In the exemplary embodiment the input devices may be used forproviding identifying inputs such as indicia read from cards,alphanumerical data, numerical data and/or biometric data which may beused to identify a particular user of the machine and/or their accounts.In exemplary embodiments the card reader is operative to read data fromor on user cards, that corresponds to at least one of a user and/or auser's financial account or accounts. The card data may be utilized forpurposes of comparison with data stored in the system in which the ATMis connected to determine if the user is an authorized user of themachine, and to enable transactions that include the transfer and/orallocation of monetary value. Exemplary card readers may includemagnetic stripe readers, smart card readers, radio frequencyidentification (RFID) readers, inductance readers or other types ofcontact or contactless readers. In addition, the exemplary input devicesare also operative to receive transaction inputs which cause the ATM tocarry out selected transaction functions. It should be understood thatthese input devices are exemplary and in other embodiments other typesof input devices may be used.

The exemplary user interface 15 further includes output devices. Theoutput devices of the exemplary embodiment include a display 24, aspeaker 26 and a headphone jack 28. The output devices of the exemplaryembodiment are operative to output indicia either visual, audible orboth, which are usable to operate the ATM. For purposes of thisdisclosure the display shall be deemed to include an output device suchas a CRT or LCD as well as the associated circuitry which producesoutputs from the display. Of course the output devices shown in userinterface 15 are exemplary and in other embodiments other or additionaloutput devices may be used.

The exemplary ATM 10 further includes other transaction functiondevices. These transaction function devices include a receipt printer 30which is operative to provide receipts to users of the machine. As shownin more detail in the interior view of the machine shown in FIG. 2, thereceipt printer includes a paper supply 32 which supplies paper on whichreceipts are printed by a printer mechanism 34. Printed receipts arethen transported to the receipt opening in the fascia 12 by a transport36. In exemplary embodiments the receipt printer used may be of the typeshown in U.S. Pat. No. 5,850,075, the disclosure of which isincorporated herein by reference. Of course in other embodiments othertypes of receipt printers may be used.

The exemplary ATM 10 user interface includes on the fascia as shown inFIG. 1, a cash dispensing opening 38 and a cash accepting opening 40.Each of these openings is in operative connection with correspondingtransaction function devices as later discussed, and each has anassociated gate mechanism which operates to block access through theopening except at appropriate times during transactions by authorizedusers. In the exemplary embodiment the cash dispensing opening is showncontrolled by a gate 42 and the cash accepting opening is controlled bya gate 44. It should be understood that the fascia and devicesassociated with ATM 10 are exemplary and in other embodiments other ordifferent fascia configurations and devices maybe used.

In the exemplary embodiment the user interface of the machine includes aplurality of multicolor light emitting devices 17, 31, 41, 43 and 45.Each of the light emitting devices is positioned at a location adjacentto the location on the user interface which is associated with aparticular transaction function device. For example, light emittingdevice 17 is positioned adjacent to the opening to card reader 16.Likewise, light emitting device 31 is positioned adjacent to the slotfor delivery of receipts. Likewise, light emitting device 41 isassociated with cash-accepting opening 40, and light emitting device 43is associated with cash-dispensing opening 38. As later explained, inthis exemplary embodiment the multicolor light emitting devices areselectively operated to output light of a particular color responsive toconditions of the associated transaction function device. Such featuresmay be used to guide a user in operation of the machine, provideindications concerning the status of devices, alert a user to particularconditions, or provide improved aesthetics for the machine.

As shown in FIGS. 2, 3 and 6, ATM 10 includes a housing 46 which extendsgenerally on an interior side of wall 14. Housing 46 includes a chestportion 48. In the exemplary embodiment chest portion 48 is a generallysecure chest which has a safe-like access door 50. Access to theinterior of the chest portion is limited to authorized personnel througha suitable locking mechanism schematically indicated 52 (see FIG. 3). Inthe exemplary embodiment the chest is generally L-shaped in crosssection.

Housing 46 further includes an upper portion 54. Upper housing portion54 which is in connection with the fascia, is in supporting connectionwith the chest portion 48. In the exemplary embodiment upper housingportion 54 has in association therewith, access doors 56 and 58. Accessto the upper housing portion is controlled by one or more lockingmechanisms in operative connection with access doors 56 and 58 asrepresented by key locks 60 and 62. In the exemplary embodiment thesecure chest portion 48 is used to house financial instrument sheetssuch as currency notes, checks and other valuable sheets. The upperhousing portion 54 is generally used to house components of the machinethat do not hold on an extended basis notes or other financialinstrument documents which can be redeemed for value. For purposes ofthis 5 disclosure a cash dispenser shall be considered to include adevice that operates to deliver cash stored inside the machine to alocation accessible by a machine user outside of the machine. Of courseit should be understood that the construction of ATM 10 is exemplary andin other embodiments other approaches may be used.

As schematically shown in FIG. 2, ATM 10 includes at least onecontroller schematically indicated 64. In the exemplary embodimentcontroller 64 includes at least one processor and is in operativeconnection with at least one data store schematically indicated 66. Acontroller or processor may be alternatively referred to herein as acomputer. In the exemplary embodiment the data store is operative tohold data representative of instructions such as computer programs,configuration parameters, data about transactions conducted and otherinformation that may be usable in the operation of the ATM 10. Forpurposes of this disclosure, references to a single processor orcomputer will be deemed to include references to multiple processors andcomputers, and vice versa. Likewise, reference to a single data storeshall be deemed to include references to multiple data stores, and viceversa.

Controller 64 is in operative connection with numerous transactionfunction devices within the ATM, and is operative to control theoperation thereof in accordance with its programming. Controller 64 isshown schematically in operative connection with devices 68, 70 and 72.It should be understood that this representation is schematic only andis intended merely to represent numerous components within the machinewhich are in operative connection with the controller and the at leastone processor included therein. For example the transaction functiondevices may include moving devices such as motors, solenoids and otherdevices that are operative to impart motion to components. Likewisetransaction function devices may include sensors such as radiationsensors, proximity sensors, switches and other types of sensors that areoperative to sense items, users, conditions, properties, characteristicsor components within the ATM and to enable a controller to performfunctions in accordance with its programming. Transaction functiondevices include output devices such as sound emitters and light emittingdevices. For example and without limitation, transaction functiondevices may include the card reader, display, keyboard, function keys,printer, cash dispenser, cash acceptor, storage mechanisms and otherdevices previously discussed as well as other devices within the machinewhich are operative in response to the controller.

In the exemplary embodiment the controller is also in operativeconnection with a communications device schematically indicated 74. Thecommunications device is operative to communicate messageselectronically between the ATM 10 and other computers in financialtransaction processing systems or other systems or networks. These mayinclude for example communications with systems operated by banks,credit card networks, automated clearinghouses and other entities. InFIG. 2 the communications device 74 in the ATM 10 is schematically shownas providing communication with a financial institution 76 through anetwork 78. It should be understood that this communicationconfiguration is exemplary and in other embodiments other communicationarrangements may be used.

As represented in FIGS. 2 and 6, in the operative position of ATM 10 thehousing 46 houses a sheet acceptor mechanism 80 which is also referredto herein as a cash acceptor mechanism. In the exemplary embodiment themechanism 80 is operative to accept sheets from a machine user throughthe opening 40, to analyze each sheet for at least one property orcharacteristic, and to route the sheets selectively for storage withinthe housing of the machine based on the characteristics analyzed. Itshould be understood that in various embodiments these sheets mayinclude currency notes, checks or other financial instrument sheets. Forpurposes of this disclosure currency notes are alternatively referred toas currency bills. It should further be understood that in exemplaryembodiments the financial instrument sheets may be sheets comprised ofdifferent types of material such as paper, plastic or combinationsthereof. It should further be understood that references herein to acash acceptor mechanism shall be deemed to encompass mechanisms whichhandle not only currency notes, but also other financial instrumentsheets such as checks, money orders, gift certificates, vouchers, scripand/or other items that correspond to value.

As represented in FIG. 2, cash acceptor mechanism 80 includes a chute 82which extends through opening 40 in fascia 15 in its operativecondition. As previously discussed the user accessible opening to chute82 is controlled by a movable gate 44. Gate 44 moves responsive to thecontroller 64 and enables authorized users to access the chute atappropriate times during transaction sequences.

In operation of the machine users are enabled to insert a stack offinancial instrument sheets schematically indicated 84, into the chute.The stack 84 may comprise currency notes, 5 checks or other forms offinancial instrument sheets.

In operation of the cash acceptor mechanism sheets are individuallyseparated from the stack by a picker mechanism 86, an exemplaryembodiment of which is later discussed in detail. Each picked sheet istransported individually from the picker mechanism past the validatordevice schematically indicated 88. The validator device 88 of theexemplary embodiment is operative to determine at least onecharacteristic of each sheet. This may include for example adetermination as to whether the sheet is a note or check and if a note,the denomination and whether it is valid. If the document is a check, adetermination may be made as to whether the check is genuine as well asthe indicia associated with the maker of the check and the amountthereof. For example in some exemplary embodiments the validating devicemay be of the type shown in U.S. Pat. No. 5,923,415, the disclosure ofwhich is incorporated herein by reference. Alternatively or additionallya validating device having features disclosed in U.S. Pat. No. 6,554,185and/or U.S. Pat. No. 7,137,551, the disclosures of each of which areincorporated herein by reference, may be used. Of course in otherembodiments other types of validating devices such as imagers, readers,sensors and combinations thereof may be used. For example, in someembodiments the sheet accepting device may be operative to imageinstruments such as checks and provide data which can be stored andtransmitted as an electronic reproduction of that check. In suchcircumstances an electronic reproduction of the check may be transmittedto remote locations so as to facilitate review and validation of thecheck. Alternatively or in addition, the electronic representation ofthe check may serve as a substitute for the physical paper check whichthereafter enables the paper check to be cancelled and subsequentlydestroyed. This may be done in the manner described in U.S. patentapplication Ser. No. 11/370,430 filed Mar. 8, 2006 the disclosure ofwhich is incorporated herein by reference.

In the exemplary embodiment of the cash acceptor mechanism 80, sheetswhich have been analyzed through operation of the validator device 88are moved through a transport 90 to a routing device 92. The routingdevice is operative responsive to the controller 64 to route sheets 13selectively to either an escrow device 94 or to a transport 96. Escrowdevice 94 generally operates to hold sheets in storage on a temporarybasis. Such an escrow device may be of the type shown in U.S. Pat. No.6,371,368, the disclosure of which is incorporated by reference herein.Escrow device 94 may be operative to accept sheets and store them.Thereafter responsive to operation of the controller 64 the escrowdevice may deliver those sheets to the routing device 92 which directsthem along sheet paths in the machine to carry out transactions. Ofcourse it should be understood that the escrow device shown is exemplaryand in other embodiments other types of escrow devices may be used.

In the exemplary embodiment transport 96 is used to receive unacceptablesheets which have characteristics that do not satisfy certain parametersset by the machine. These may include for example, notes which have oneor more characteristics which suggest that they are counterfeit. Inother embodiments such sheets may include checks which have propertieswhich suggest that they are reproductions or forged or otherwiseunacceptable. Of course in other embodiments other sheets may be deemedunacceptable. As schematically represented in FIG. 2, sheet acceptormechanism 80 is operated to cause transport 96 to deposit suspect sheetsschematically indicated 98 in a storage area 100. In the exemplaryembodiment the suspect sheets are stored within the cash acceptormechanism and outside of the secure chest so that they may be recoveredby servicing personnel in a manner that is later discussed. Of coursethis approach is exemplary and in other embodiments other approaches maybe used.

In the exemplary embodiment the cash acceptor mechanism 80 is operativeresponsive to signals from the controller 64 to cause financialinstrument sheets that are determined to be valid or otherwiseacceptable, to be directed through a cash accepting opening 102 thatextends in an upper surface 104 of the chest. In the operative positionof the cash acceptor mechanism shown in FIG. 2, the transport in thecash acceptor mechanism is aligned with the cash accepting opening and atransport 108 that extends into the secure chest. As schematicallyrepresented in FIG. 2, in the operative position of the cash acceptormechanism 80 at least one driving member 110 of the transport 106 is inoperative connection with a driven member 112 of the transport 108. Inthe exemplary embodiment this enables the cash acceptor mechanism totransmit movement to sheet handling mechanisms within the secure chestand to assure coordinated movement of processed sheets therein. Furtherin the exemplary embodiment the driving and driven members extend in thecash accepting opening so as to block access therethrough byunauthorized persons as later discussed.

In the exemplary embodiment when the cash acceptor mechanism is movedfrom the operative position shown in FIG. 2 to a servicing position suchas shown in FIGS. 12, 13 and 14, the driving member 110 and the drivenmember 112 disengage. In some exemplary embodiments the movement of thecash acceptor mechanism from the operative position to a servicingposition may include movably mounting the cash acceptor mechanism suchthat the mechanism moves both upward away from the secure chest so as todisengage the driving and driven members as well as outward for purposesof servicing. Of course to return the cash acceptor mechanism to theoperative position, movement thereof is made both inward and downward soas to reengage the driving and driven members. This may be accomplishedby a combination of slides, rollers or other suitable mechanisms. Ofcourse the approach described of providing for engagement between thecash acceptor mechanism and a mechanism for handling sheets within achest portion is exemplary and in other embodiments other approaches maybe used, or the transport within the chest portion may have a separatemotor or other moving device.

As shown in FIG. 2, transport 108 which moves sheets generally in avertical direction through the cash accepting opening is in operativeconnection with a horizontal transport schematically indicated 114. Thehorizontal transport is operative to engage sheets moved into the chestportion and to move them transversely away from the cash acceptingopening. The horizontally extending transport 114 is in operativeconnection with a vertically extending transport 116 which istransversely disposed from the cash accepting opening in the securechest.

Vertical transport 116 is operative to move sheets selectively intoengagement with sheet handling mechanisms 118, 120, 122 and 124. In someexemplary embodiments, sheet handling mechanisms 118, 120, 122 and 124maybe sheet stacking mechanisms such as those shown schematically inFIGS. 5 and 6. Alternatively or in addition in other embodiments one ormore of the sheet handling mechanisms may include sheet receiving anddispensing mechanisms which are operative to selectively accept sheetsfor storage as well as to dispense sheets therefrom. Examples of sheetaccepting and stacking mechanisms as well as sheet accepting, stackingand dispensing mechanisms which may be used in some exemplaryembodiments are described in detail in U.S. Pat. Nos. 6,302,393 and6,290,070, the disclosures of each of which are incorporated byreference.

As shown schematically in FIG. 4, the exemplary sheet accepting andstacking mechanism 118 is selectively operative to accept a sheet 126moving in the vertical transport 116. Sheet 126 is guided to engage thesheet handling mechanism 118 through movement of a gate member 128. Thegate member moves responsive to the controller 64 to direct the leadingedge of the sheet into a recess 130 of a rotatable member 132. As theleading edge of the sheet 126 enters the recess 130 the rotatable member132 rotates in the direction of Arrow R. This causes the gripper portionbounding the recess 130 to move inwardly capturing the sheet 126therein. The rotatable member 132 rotates until the leading edge of thesheet 126 engages a stop surface 136 at which time the gripper portion134 has moved radially outward such that the sheet disengages from therotatable member 132 and is integrated into a sheet stack 138. Stack 138may be for example a stack of currency notes all of which are of thesame denomination. Of course in other embodiments the stack 138 may be acollection of other types of sheets.

In the exemplary embodiment the stack is maintained in abutting relationwith the rotatable member by a biasing plate 140 which acts against theback of the stack. The biasing plate 140 is movable responsive to abiasing mechanism 142 which is operative to enable the stack to increaseor decrease while maintaining the sheets in an appropriately alignedposition. Further details related to an exemplary embodiment of thesheet handling mechanism are described in the incorporated disclosure ofU.S. Pat. No. 6,302,393.

FIG. 5 further shows the exemplary operation of exemplary sheet handlingmechanisms 118 and 120. In this case a sheet 142 moving in transport 116is enabled to pass the rotatable member 132 when the gate member 128remains retracted as the sheet passes. This enables the sheet to move toother sheet handling mechanisms such as sheet handling mechanism 120.This arrangement enables sheets having particular characteristics to bestored together, for example, valid currency notes of differentdenominations to be collected in stacked relation in selected sheetstorage areas. Alternatively in other embodiments sheets of similartypes such as checks may be segregated from other financial instrumentsheets such as notes or travelers checks. In still other embodimentssheets which are to be recycled such as suitable fit currency notes canbe segregated from valid yet worn or soiled currency notes which are notsuitable for providing to customers. It should be understood that theseapproaches are exemplary and in other embodiments other approaches maybe used.

In the exemplary embodiment shown in FIG. 2, a security plate 144extends within the secure chest in intermediate relation between thehorizontal transport 114 and the note storage mechanism such as thestorage area 146 associated with sheet handling mechanism 118. Thesecurity plate 144 in the exemplary embodiment is secured within theinterior of the secure chest and is adapted to prevent unauthorizedaccess through the cash accepting opening 102 in the chest. This may beaccomplished by securing the security plate 144 to the walls boundingthe interior of the secure chest or other suitable structures. As can beappreciated in the exemplary embodiment the upper housing portion 54houses the sheet acceptor mechanism 80, it is generally easier to accessthe area housing the sheet acceptor mechanism than the secure chest. Incases where criminals may attack ATM 10 and attempt to remove the sheetaccepting mechanism, ready access through the cash accepting opening isfirst blocked by the driving and driven members and other components ofthe transports 106 and 108. However, in the event that criminals attemptto clear away the transport mechanism components, access to the storedsheets in the note storage mechanisms is still blocked by the securityplate. FIG. 11 shows greater detail of the cash acceptor mechanism 180retracted to a servicing position so as to expose the cash acceptingopening. In the exemplary embodiment the cash acceptor mechanism ismovably mounted in supporting connection with the chest portion onsuitable slides or other members. As can be appreciated in thisexemplary embodiment the security plate 144 operates to separate thecash accepting opening 102 from the notes or other valuable financialinstrument sheets which are stored below the security plate within thesecure chest. Of course the security plate is exemplary and other formsof security plates or other structures may be used.

In an alternative embodiment the ATM includes a bulk storage container260 shown in FIG. 20 for holding currency bills, notes, checks or otheritems that have been deposited into the machine. The container 260includes a top wall 262 with an opening 264 which corresponds to opening102 in the chest when the container 260 is in the operative position.Container 260 includes a transport 266 which transports items that passthrough the opening 264 into an interior area 268 of the container. Ahorizontal transport 270 is operative to move deposited itemstransversely away from the opening 264. A security plate 272 ispositioned to reduce the risk of unauthorized access to the interiorarea 268. A further transport 274 is operative to move deposit itemssuch as currency sheet 276 to a suitable location for being dispatchedinto the interior area 268 below the security plate. Deposited itemsschematically represented 278 are held within the interior area of thecontainer 260.

In the exemplary embodiment the container 260 includes a bottom wall280. The interior area 268 is bounded by a shaker member 282 that isdisposed vertically above the bottom wall. In the exemplary embodimentthe shaker member comprises a resilient flexible membrane 284. A rigidplate 286 extends in underlying relation of a central portion of themembrane. Flexible supports 288 support the rigid plate 286 above thebottom wall 280. The flexible supports further enable movement of therigid plate and membrane relative to the bottom wall. In exemplaryembodiments the rigid supports 288 may include springs or other memberswhich enable relative vertical and/or horizontal movement of the bottomwall and the rigid plate.

In the exemplary embodiment an actuator 290 extends in intermediaterelation between the bottom wall and the rigid plate. In exemplaryembodiments the actuator is an electrical vibrating device which isoperative to shake the rigid plate and overlying membrane. The shakingaction of the actuator 290 is operative to impart shaking motion to thedeposited items 278 that are in supporting connection with the membrane.This facilitates the dispersal and settling of deposited items andenables a relatively larger quantity of such items to be collectedwithin the interior area 268 before such items need to be removed. Inexemplary embodiments the actuator 290 is electrically connected to thecircuitry within the machine through a releasable connector 292. Thisfacilitates removal of the exemplary container as hereafter discussed.In addition, in some embodiments the moving devices for transportswithin the container may be supplied with signals and/or electricalpower through the releasable connector.

In operation of the machine, the interior area 268 of the container 260is in operative connection with the opening 38 in the housing of themachine through which deposited items are accepted. The deposited itemsare passed through the cash accepting mechanism or other mechanism forprocessing such items. Items appropriate for deposit in the containerare passed through the opening 102 in the top of the chest. Such itemsare transported by the transports 266, 270 and 274 to the area below thesecure plate 272 and accumulate within the interior area 268.Periodically responsive to the controller, the actuator 290 operates toimpart shaking motion to the deposited items 278 within the interiorarea. This facilitates settling of the items so as to densely pack theitems therein. Sensors 294 may be included within the interior area soas to sense the deposited items. The controller may be operative tocause the actuator to shake deposited items responsive to the sensingthe level of such items by the sensors. Alternatively the controller maybe operative to shake deposited items based on elapsed time, number ofitems deposited, or other programmable bases. In the exemplaryembodiment the sensors 294 may be in operative connection with thecontroller through the releasable connector 292.

The exemplary container 260 is removably mounted within the securechest. The exemplary container is supported on rollable supports 296.The rollable supports 296 may be castors, wheels, ball rollers or othertype items that enable more ready movement of the container in a loadedcondition. In the exemplary embodiment upon opening of the secure chestthe container 260 is enabled to move outward from the chest. This isfacilitated by a servicer grasping a handle 298 which is attached to thecontainer. The releasable connector 292 is enabled to be disconnected sothat the container 260 can be pulled outward from the secure chest. Asshown in greater detail in FIG. 21, in the exemplary embodiment thehandle 298 is a telescoping handle that is enabled to be moved upwardonce the handle has cleared the secure chest. This facilitates movingthe container outside of the ATM. Thereafter the container may be movedto a suitable location by the handle away from the ATM for purposes ofremoving the contents. This may be, for example, an area within a vaultor other secure room in which the items within the container may beprocessed.

As represented in FIG. 21, the container 260 in the exemplary embodimentincludes a door 300. Access to door 300 is controlled by one or morelocks represented 302. In the exemplary embodiment door 300 is shownhinged at a side toward the chest door so as to reduce the risk ofpersons obtaining unauthorized access to the interior of the containerwhen the container is within the machine. Once the container has beenmoved to a suitable location, the lock 302 may be unlocked; the dooropened, and deposited items removed. After the items have been removed,the door 300 may be returned to the closed position. Thereafter thecontainer may be reinstalled in the machine with the handle 298 beingretracted so as to enable the container to again be aligned with opening102. Further, the releasable connector 292 may be reconnected so as toagain enable operation of the container within the machine.

As can be appreciated, the exemplary container 260 is enabled to hold asubstantial quantity of deposited items. Further, the constructionincluding the rollable supports and telescoping handle facilitatesmovement of the loaded container out of the ATM and the container intothe ATM. It should be understood that the container is exemplary and inother embodiments other approaches may be used. These may include, forexample and without limitation, containers which include multipleinterior areas in which deposited items are supported on shakingmembers. Such embodiments may achieve, for example, a separation ofdeposited notes, checks and/or envelopes by denomination or deposittype, and achieve more densely packed storage within a particularinterior compartment within the container. In addition or in thealternative, in other embodiments shaking members may be provided onside walls or on top walls bounding the container so as to facilitatethe shaking of deposited items and the packing and storage thereof. Inaddition or in the alternative, containers may be used in someembodiments in conjunction with sheet handling mechanisms such thatcertain sheets are stored precisely positioned in containers forpurposes of stacking and/or recycling while other sheets are stored inbulk within a container or compartment within a container. Thesealternatives are encompassed within the teachings of the presentinvention.

FIGS. 7 through 10 schematically describe an exemplary embodiment of thepicker mechanism 86 used in the cash accepting mechanism 80. In thisexemplary embodiment the stack of sheets 84 is positioned in the chute82 and is in supporting connection with a generally angled lower surface148. Moving members 150 and 152 are operative to engage the stack andselectively rotate responsive to a motor or other mechanism in thedirection of Arrow P so as to move the stack into generally abuttingrelation with an engaging surface 154. Positioned adjacent to theengaging surface 154 in proximity to the lower surface 158 is an idlerroll 156 which is a generally free wheeling roll. The engagement of thestack 84 of the engaging surface 154 and the face of the roll 156 isoperative to splay the sheets as shown.

The picker mechanism 86 further includes a generally cylindrical pickingmember 158. Picking member 158 is rotatable selectively by a motor orother driving member responsive to the controller 64. The picking memberduring picking operation rotates in the direction of Arrow P as shown.Picking member 158 further includes high friction arcuate segments 16020 which in the exemplary embodiment serve as sheet engaging portionsand which extend about a portion of the circumference of the pickingmember.

Picker mechanism 86 of the exemplary embodiment further includes aplurality of rolls 162 that serve as non-contact stripper rolls in amanner later discussed. The picking mechanism further includes a contactstripper roll 164 which biasingly engages the high friction segments 160of the picking member.

As represented in FIG. 8, the picking member is a generally cylindricalmember that includes a plurality of annular recesses 166. The outersurface of the non-contact stripper rolls 162 extend into acorresponding annular recess 166, but are generally not in strippingengagement therewith. As represented in the exemplary embodiment of FIG.8, the outer surface of the non-contact stripper rolls 162 are disposedslightly away from the base of the annular recess. As a consequence theouter surface of the non-contact stripper rolls which serve as a firststripper portion are not positioned to be in direct contact strippingengagement with the picking member. However, because the surface of suchrolls is disposed in close proximity thereto and generally enables onlya single sheet to pass between the picking member and the non-contactstripper rolls, the separation of a single sheet from other sheets isgenerally achieved. It should be understood however that while in theexemplary embodiment the noncontact stripper rolls are disposed slightlyfrom the picking member, in other embodiments such rolls or otherstripper members may operate to actually contact the picking member butmay be of such resilient consistency or other properties that the rollsare not in a biased contact stripping engagement as is the case with thecontact stripper roll 164.

As shown in FIG. 8 the contact stripper roll is biased to engage acentral sheet engaging portion 168 of the picking member. This centralsheet engaging portion is generally centered with regard to sheets thatare moved by the picker mechanism 86. This reduces the tendency ofsheets to twist or skew as they are being moved in the picker mechanism.Of course it should be understood that this arrangement is exemplary andin other embodiments other approaches may be used.

The operation of the exemplary picker mechanism 86 is represented inFIGS. 9 and 10. The picker mechanism is operative to separate sheetsindividually from the stack 84. This is done by sequentially picking afirst sheet 170 which bounds the lower end of the stack while moving thefirst sheet in a first direction generally indicated by Arrow F so as tomove the sheet away from the stack. To accomplish this, the controller64 operates motors or other moving mechanisms to cause the movingmembers 150 and 152 to rotate as the picker mechanism 168 similarlyrotates in a counterclockwise direction as shown. The rotation of thepicking member causes the high friction arcuate segments 160 which serveas sheet engaging portions to engage a lower face of the first sheet andpull the sheet in intermediate relation between the picking member andthe non-contact stripper rolls 162. As the first sheet is moved theidler roll 156 rotates to facilitate the movement of the first sheetbetween the picking member and the noncontact stripper rolls

The non-contact stripper rolls 162 are in operative connection with aone-way clutch 172 such that the first stripper rolls remain stationarywhen the first sheet is engaged therewith and moving in the direction ofArrow F. Because the resistance force provided by the non-contactstripper rolls against the face of the sheet engaged therewith is lessthan the moving force imparted to the opposed face of the sheet, thefirst sheet 170 is moved into intermediate relation between the pickingmember and the non-contact stripper rolls. This causes the sheet toassume the cross-sectional wave configuration shown in FIG. 10. This iscaused by the sheet being deformed by the non-contact stripper rollsinto the annular recesses 166 of the picker member. This cross-sectionalwave configuration is generally operative in combination with theopposing force applied by the non-contact stripper rolls, to separatethe first sheet from other sheets that may be moving therewith from thestack.

As the first sheet 170 moves further in the direction of Arrow F asshown in FIG. 9, the leading edge of the sheet then engages the contactstripper roll 164 which is biased to engage the sheet engaging portionsof the picking member. The contact stripper roll is also in operativeconnection with a one-way clutch 174 such that in the exemplaryembodiment the contact stripper roll remains stationary as the firstsheet moves in the direction of Arrow F. The engagement of the contactstripper roll and the first sheet operates to displace the contactstripper roll so as to enable the sheet 170 to move in intermediaterelation between the contact stripper roll and the central sheetengaging portion 168. The resistance force of the non-contact stripperroll is generally operative to separate any sheets other than the firstsheet 170 from moving in the direction of Arrow F.

As shown in FIG. 9 the sensor 176 is positioned adjacent to the contactstripper roll in the exemplary embodiment. Sensor 176 is operative tosense the presence of double sheets which may have been able to pass thenon-contact and contact stripper rolls. Suitable sensors in someembodiments may be those shown in U.S. Pat. Nos. 6,241,244 and6,242,733, the disclosures of which are incorporated herein byreference. Upon sensing a double sheet the controller of the machine isenabled to make additional attempts to strip the sheet as laterdiscussed. However, in the event that only a single sheet is sensed thepicker member 158 continues moving in the counterclockwise directionuntil the leading edge of the sheet reaches takeaway rolls 178. In theexemplary embodiment takeaway rolls are operative to engage the sheetand to move the sheet in the cash accepting mechanism toward thevalidator device 88. In the exemplary embodiment one rotation of thepicking member is operative to separate one sheet from the stack.

In the event that the sensor 176 senses that a double sheet or othermultiple sheet has been able to pass the contact and non-contactstripper rolls, the controller of this exemplary embodiment is operativeto stop the movement of the picker member 158 in the counterclockwisedirection as shown prior to the first sheet 170 being disengagedtherefrom. Thereafter the controller is operative to reverse thedirection of the picker member 158 and the moving members 150 and 152 soas to move the first sheet back toward the stack. Through the operationof one-way clutches 172 and 174 the contact stripper roll 164 and thenon-contact stripper rolls 162 are enabled to rotate in acounterclockwise direction as shown so as to facilitate the return ofthe sheets to the stack. Thereafter the controller may operate thepicker mechanism 86 to again pick a single bill. Repeated attempts maybe made until a single sheet is separated from the stack so that it maybe processed by the cash acceptor mechanism.

It has been found that the exemplary embodiment of the picker mechanism86 is well adapted for separating various types of financial instrumentsheets having different properties. In general, sheets such as currencynotes that are new or other types of sheets which have generallyconsistent properties of rigidity and friction from sheet to sheet areseparated through the operation of the picker mechanism and thenon-contact stripper rolls. However, in situations where rigidity andfrictional properties vary substantially from sheet to sheet, thecontacting stripper roll which subsequently engages the sheets afterthey have engaged the non-contact 23 stripper rolls is effective inseparating sheets that would not otherwise be separated. This may beparticularly helpful for example in processing sheets that may includeplastic and paper currency notes, checks or other documents that havesignificantly variable properties and which are mixed together in astack from which the sheets must be individually picked.

It should be understood that while picking rolls and cylindrical membersare used in the exemplary embodiment, in other embodiments other pickingand stripping structures such as belts, pads, fingers and other membersmay be used.

The exemplary embodiment of ATM 10 comprises a through-the-wall typemachine in which the fascia is exposed to the elements. As a result,rain and snow may impact on the fascia and in the absence of suitablemeasures may enter the machine. As can be appreciated the cash acceptingopening 40 in the fascia must be sufficiently large to accept the chute82 which holds a stack of documents 84 as previously discussed. Duringtransactions when an authorized user indicates that they wish to insertthe stack of sheets into the chute, the gate 44 must be opened whichresults in exposure of the chute to the elements.

To minimize the risk posed by rain and snow to the currency acceptormechanism 80, the exemplary embodiment includes the capability tocapture and direct from the machine moisture which may enter the chute.The approach used in the exemplary embodiment is represented in FIGS. 17through 19. As shown in FIG. 17, the lower surface of the chute 148includes at least one water accepting opening 180 therein. In theexemplary embodiment the water accepting opening comprises one or moretroughs which extend transversely across the lower surface of the sheet.Of course in other embodiments other approaches may be used. The fluidaccepting openings are in fluid connection with a conduit schematicallyrepresented 182 which is in fluid connection with a drain 184 whichdelivers the water outside the ATM. As represented in FIGS. 18 and 19the trough 180 is in operative connection with a fluid fitting 184 whichconnects to a generally flexible fluid conduit 182 such as a tube. Theconduit 182 connects to the drain 184 which in the exemplary embodimentincludes a cavity at a lower side of the fascia and which includesopenings through which the water may drain to the outside of the machinehousing.

In the exemplary embodiment a tube support 186 is positioned to controlthe direction of the tube and assure drainage when the cash acceptormechanism is in the operative position as well as when the cash acceptormechanism is in a service position such as is shown in FIG. 12. In theexemplary embodiment the tube support minimizes the risk of the fluidconduit being crimped or otherwise assuming a position which preventsthe drainage of water from the interior of the chute to the outside ofthe machine. It should be understood, however, that the approach shownis exemplary and in other embodiments other approaches may be used.

In the exemplary embodiment, provision is made to minimize the risk ofmoisture entering the ATM in the area of the cash accepting openingthrough which the chute 82 extends in the operative position of the cashacceptor mechanism 80. As shown in FIGS. 18 and 19, in the exemplaryembodiment a resilient gasket 188 extends in surrounding relation of thechute 82 in the area adjacent to the fascia. The resilient gasket issupported on a front face of the cash acceptor mechanism. As shown inFIG. 19, when the cash acceptor mechanism 80 is positioned such that thechute extends through the cash acceptor opening 40 in the fascia, theresilient gasket is positioned in sandwiched fluid tight relationbetween the front face of the cash acceptor mechanism and the interiorface of the fascia. As the seal provided by the gasket extends insurrounding relation of the chute, the risk of moisture or othercontaminants entering the ATM through the cash acceptor opening isminimized. Of course it should be understood that this approach isexemplary and in other embodiments other approaches may be used.

As discussed in connection with FIG. 2, the cash acceptor mechanism 80in response to operation of the validator device 88 and the controller64 determines at least one characteristic indicative of whetherfinancial instrument sheets are acceptable to the machine. In theexemplary embodiment unacceptable sheets may be suspect sheets such aspotentially counterfeit notes, invalid checks or other unacceptabledocuments. When such documents are detected, they are directed to astorage area 100 which in the exemplary embodiment is within the cashacceptor mechanism and outside the chest portion. Periodically theseunacceptable sheets must be recovered by servicing personnel forpurposes of either verifying the invalidity of the sheets or forpurposes of tracing the sheets to the user who placed them in themachine. In the exemplary embodiment such sheets are recoverable byauthorized persons who have access to the upper housing portion 54 butwho may be prevented from having access to the chest 48 where documentsdetermined to be valid are stored.

In the exemplary embodiment access to the storage area 100 is controlledby a suitable access device. In one form of such an access device shownin FIG. 12, an opening 190 is provided to the storage area 100. Accessto the opening is controlled by a flip-down access door 192. In someembodiments, the flip-down access door 192 may be opened only when thecash acceptor mechanism 80 has been moved rearward to extend outside ofthe housing subsequent to opening access door 58. In some embodimentsthe flip-down access door may be provided with a locking mechanism 194such as a key lock or other suitable locking mechanism. As a result inthis exemplary embodiment in order to access the sheets in the storagearea 100, the user could be required to have the necessary capabilitiesthrough keys, combinations or otherwise to unlock both lock 62 on accessdoor 58 as well as lock 194 and flip-down door 192 in order to accessthe sheets. It should be understood, however, that although in theembodiment shown the cash acceptor mechanism 180 is shown retracted outof the machine to facilitate opening the flip-down door and extractingthe sheets, in other embodiments the flip-down door may be sized,segmented or otherwise adapted such that the cash acceptor mechanism maynot need to be retracted from its operative position in order to accesssheets in the storage area 100.

FIG. 13 shows yet a further alternative for accessing sheets in thestorage area 100. In this exemplary embodiment an opening 196 isprovided through the storage area so as to enable access to the sheetstherein. Access through opening 196 is provided to a sliding door 198.Door 198 is operative to slide along the direction of Arrow S in opposedtracks, slots or other suitable mechanisms for holding and guiding thedoor in supporting connection with the cash acceptor mechanism. In someembodiments door 198 may include a locking mechanism 200. Lockingmechanism 200 may be a suitable key, combination or other lockingmechanism for assuring that only authorized personnel are enabled toaccess the documents in the storage area. As can be appreciated fromFIG. 13, door 198 may be both unlocked and opened without having toretract the cash accepting mechanism rearward. In some embodiments thismay serve to speed servicing and the removal of invalid sheets from themachine.

FIG. 14 shows yet another exemplary embodiment for accessing sheets inthe storage area 100. In this embodiment an opening 202 is provided in arear face of the cash accepting mechanism 80. Access to opening 202 iscontrolled by a door 204. In the exemplary embodiment door 204 is asliding door adapted to be selectively moved in tracks, slots or similar26 devices. In some embodiments a suitable locking mechanismschematically indicated 206 is used to assure that only authorizedpersonnel have access to the door. In the embodiment shown in FIG. 14, atransport 208 is provided for moving the sheets in the storage area 100to the service personnel through the opening 202. A transport 208 may beoperative in response to provided inputs to input devices by theservicing personnel or may be automatic responsive to the opening of thedoor 204. Of course it should be understood that all of the approachesshown are exemplary and in other embodiments other approaches may beused.

In some exemplary embodiments suspect notes or other documents arecorrelated with particular transactions conducted at the machine and/orwith particular users of the machine. This may be accomplished throughoperation of the validator and the controller. In some exemplaryembodiments the suspect documents in storage may be arranged in aparticular order and the controller is operative to provide one or moreoutputs such as through a screen or a printer indicating thetransactions and/or users which correspond to the suspect sheets.Alternatively or in addition, provisions may be made for the cashacceptor mechanism to be in operative connection with a printer whichprints transaction and/or user identifying information on each of thesuspect sheets. This may include for example, visible or non-visibleindicia. In some embodiments the indicia may be removable such asremovable labels or indicia that can be washed off or otherwise removedor neutralized. In other embodiment the characteristics determined bythe validator may be such that the data is sufficiently detailed and oftypes that create a unique electronic profile of each suspect sheet.This data can be stored at the machine in a data store through operationof the controller or elsewhere in a connected data store. This sheetidentifying data may then later be used by a servicer or other personsrecovering or analyzing the suspect sheets to correlate each sheet withthe transaction and/or user that provided the sheet to the machine. Thismay be done in some embodiments by putting the machine controller in amode for such analysis and feeding each suspect sheet through the cashacceptor mechanism. The controller may then operate to correlate thestored data related to the transaction and/or user with the stored datathat uniquely identifies the sheet. Such information is then provided toa user of the machine recovering the sheets. Alternatively, suchanalysis may be conducted by transferring data away from the machinealong with the suspect sheets, and conducting the analysis at anothervalidator. Of course these approaches are exemplary of 27 approachesthat may be used to uniquely identify a suspect sheet and associate itwith a user and/or a transaction.

In the exemplary embodiment of the cash acceptor mechanism 80, it isdesirable to maintain the interior components of the cash acceptormechanism isolated and in sealed relation except when access is requiredfor servicing. As can be appreciated, while the exemplary embodimentpositions the cash acceptor mechanism in intermediate relation between avertically extending wall of the generally L-shaped chest and the wallof the housing to provide enhanced security, it also presents challengesfor servicing. While the ability of the exemplary embodiment to move thecash acceptor mechanism rearward through a service opening of the ATMfacilitates servicing, problems are still potentially presented by theneed to have to remove cover panels and the like. Further, there isalways a risk that cover panels, once removed, will not be replacedresulting in infiltration of contaminants to the cash acceptor mechanismand causing malfunctions or failures.

To reduce the risk of service persons not replacing service panels, theexemplary embodiments are made to minimize the risk that service panelswill be removed and not replaced. As shown in FIG. 15, in one exemplaryembodiment a side service panel 210 is mounted in hinged relation insupporting connection with the cash acceptor mechanism. This enables theservice panel 210 to be opened once the cash acceptor mechanism has beenmoved rearward from the machine. This enables ready access to thecomponents within the machine. In addition in this exemplary embodiment,the front service panel 212 is mounted in hinged relation adjacent thefront of the cash acceptor mechanism. This front service panel enablesaccess to components accessible through a front opening of the cashaccepting mechanism.

As can be appreciated because of the hinged character of service panels210 and 212, the panels may be readily opened. However, the hingedmounting makes it difficult for a technician to entirely remove thepanels from the machine. Further the cash acceptor mechanism cannot bereturned to service without closing the service panels. Of course as canbe appreciated, suitable latching mechanisms or other holding devicesmay be used so as to assure that once the service panels are returned totheir closed position, they remain therein until such time as theservice panels need to be opened again for servicing.

FIG. 16 shows yet a further schematic view of an alternative approach toproviding service panels on the cash acceptor mechanism 80 that provideprotection for internal components and yet can be readily removed forservicing. In the embodiment shown in FIG. 16, service panels 214 and216 are provided such that they can move in the direction indicated bythe adjacent arrows. Service panels 214 and 216 in the exemplaryembodiment are mounted in channels, slots or other suitable devices onthe cash acceptor mechanism for guiding and holding the panels inposition. The useful aspect of the service panels shown in FIG. 16 isthat the cash acceptor mechanism 80 need not be removed from theoperative position in order to open the interior of the mechanism bymoving the service panel. Indeed in the exemplary embodiment, servicepanel 214 may be entirely removed exposing the components of the cashacceptor mechanism without moving the cash acceptor mechanism from theoperative position. Service panel 216 which may include the front facesupporting the resilient gasket, may be made more readily removable bymoving the gasket relative to the chute. The ability to remove servicepanels may be particularly useful in situations where a service personneeds to observe the cash acceptor mechanism in operation in order todiagnose and remedy certain problems.

In some embodiments it may be desirable to include devices to assurethat the service panels 214 and 216 are reinstalled on the cash acceptormechanism after servicing procedures are completed. This may beaccomplished by including contact switches such as the contact switchschematically represented as 218 to sense when the service panels havebeen placed back in position. Such contact switches may limit theoperation of the cash acceptor mechanism until such panels are replaced.Alternatively the circuitry within the ATM may cause an alarm or otherindication to be given or may disable operation of the currency acceptormechanism if the access doors to the upper housing are closed and theservice panels have not been returned to their operative position. Ofcourse other approaches may be used. As can be appreciated, thearrangements of service panels shown in FIGS. 15 and 16 for the cashacceptor mechanism are exemplary and in other embodiments otherapproaches may be used.

In the exemplary ATM 10 there is also included a mechanism fordispensing cash through the cash dispensing opening 38 in the fascia.This cash dispensing mechanism generally indicated 220 is schematicallyrepresented in FIG. 3. In the exemplary embodiment the cash 29dispensing mechanism is positioned in the higher side of the generallyL-shaped chest and includes a plurality of note storage areas 222, 224,226, 228, 230 and 232. In some exemplary embodiments the note storageareas may be housed within removable currency cassettes which aresuitable for holding notes and which may be readily removed from themachine. The exemplary cash dispenser may include features shown in U.S.Pat. No. 7,780,073 the disclosure of which is incorporated herein byreference in its entirety.

In the exemplary embodiment each of the note storage areas is inoperative connection with a picker mechanism 234, 236, 238, 240, 242 and244. Each of these picker mechanisms are selectively operativeresponsive to controller 64 to selectively dispense notes or othersheets from the corresponding storage area responsive to appropriateinputs to input devices of the user interface. In some exemplaryembodiments the picker mechanisms used may be similar to the pickermechanism 86 used to separate sheets from a stack in the cash acceptormechanism 80.

In the exemplary embodiment a vertically extending transport 246 is inoperative connection with the picker mechanisms and a presentermechanism 248. In operation of the machine the presenter mechanism isoperative to receive sheets dispensed by the picker mechanisms and tomove the sheets upward through the transport 246 to accumulate thesheets into a stack schematically indicated 250. After the desiredsheets have been accumulated, the presenter mechanism is operative tomove the stack toward the cash dispensing opening 38 while thecontroller is operative to open the cash dispensing gate 42. Thisenables the stack of sheets to be dispensed to a user of the machine.

It should be understood that while in the exemplary embodiment the cashdispensing mechanism 220 has been described as dispensing variousdenominations of currency notes; in other embodiments the cashdispensing mechanism may dispense other types of sheets. These mayinclude, for example, travelers' checks, stamps, vouchers, scrip, giftcertificates, or other documents. Further, in some embodiments the ATMmay be operative to dispense combinations of both notes and otherdocuments as may be requested by the user. Of course the mechanismsshown are exemplary and in other embodiments other approaches may beused.

In operation of the exemplary ATM 10, a user operating the machineprovides inputs sufficient to identify the user's account through theinput devices of the machine. This may include, for example, providing acard and/or alpha-numeric data through the input devices which can becorrelated through operation of the controller in the machine and/or byinteraction with a remote computer to determine whether the card datacorresponds to an authorized user as well as a financial account of theuser. The controller thereafter operates the output devices of themachine so as to prompt the user to provide inputs and to select aparticular type of transaction or provide other inputs. In situationswhere the user wishes to conduct a cash accepting transaction, the ATMoperates responsive to the controller 64 to open the gate 44 to thechute 82 which enables the user to provide a stack of notes or otherdocuments into the machine.

In response to the user providing the stack of documents 84 and/or inresponse to inputs from the user, the cash acceptor mechanism 80operates to unstack the documents through operation of the pickermechanism 86 and to determine at least one of the characteristics ofeach document through operation of the validator device 88. Thedetermined characteristics of the documents may cause valid oracceptable documents to be routed through operation of the routingdevice 92 into the escrow device 94 where they may be temporarilystored. Also, the controller may operate the routing device 92 to directsuspect documents such as invalid documents or probable counterfeitnotes to the transport 86 and the storage area 100.

In the exemplary embodiment once the documents have been moved past thevalidator, the controller may operate to advise the user of themachine's determination with regard to the documents through outputsthrough one or more output devices. In some exemplary embodiments theuser may be offered the option to recover the valid or invalid documentsor both. This may be accomplished by the escrow device delivering thedocuments to the same or different transports such that the documentsmay be returned to the chute or other area of the machine that isaccessible to the user. Likewise if the option is offered, invaliddocuments may likewise be routed back to the user. Of course variousapproaches may be used depending on the particular machine configurationand the programming associated with the controller.

In the exemplary transaction, if the documents determined to be validare to be stored within the machine, the controller operates responsiveto inputs from the user and/or its programming to cause the escrowdevice 94 to deliver the documents. The documents are directed by therouting device 92 through the cash accepting opening 102 in the chest inwhich they are transported and stored in the appropriate sheet handlingmechanisms or in an appropriate bulk storage container. In the exemplaryembodiment the user's account is credited for valid sheets deposited.Information is collected concerning any invalid sheets provided by theuser so that if the sheets are later determined to be valid, the usermay be credited or alternatively the user may be contacted to determinethe source of the invalid sheets. Of course as can be appreciated, thistransaction is exemplary and in other embodiments other approaches maybeused.

Using the exemplary ATM 10 a user may also conduct cash dispensingtransactions. This may be done either during the same session as a cashaccepting transaction or as part of a separate session. In such atransaction the user of the ATM provides inputs to the input devicesthat are sufficient to identify one or more accounts of the user and/orother identifying inputs. Responsive to prompts through the outputdevices, the user provides inputs indicating that they wish to conduct atransaction involving the dispense of notes or other types of sheets,and the amount, nature or character of the sheets that the user hasrequested.

Responsive to the inputs from the user the controller 64 is operative tocause the cash dispenser mechanism 220 and the picker mechanisms locatedtherein to deliver the requested sheets to the presenter mechanism 248,which is operative to accumulate the requested sheets into a stack 250.Once the sheets are accumulated, the sheets are moved outward to theuser as the gate mechanism is opened. Hereafter the controller operatesto cause the value of the dispensed cash or other sheets to be chargedto the user's account.

Some embodiments may be useful in handling sheets that includeprogrammable tracking devices or other programmable memory devicesthereon. For example some embodiments may be useful in handling sheetsthat include programmable radio frequency identification (RFID) datastores thereon. Still other types of sheets may include programmabletracking devices that have processing and data storage capabilities suchas for example Memory Spot™ devices available from Hewlett-Packard. Forexample in some embodiments currency bills may include programmabletracking devices that can be programmed with data that can be later readto determine information concerning the bill. Such information mayinclude data which is used to verify that the bill is genuine.Alternatively or in addition the programmable tracking devices can beused to store and deliver information about entities and/or transactionsin which the bill has been involved. In still other embodimentsprogrammable tracking devices may be used on sheets such as checks,tickets, script or other items for purposes of authenticating thegenuineness thereof and/or indicating transactions in which such itemshave been used. Of course these approaches are exemplary.

In operation of an exemplary ATM the ATM may include one or more sensorswhich are operative to sense programmable tracking devices on currencybills or other sheets. Such sensors may operate based on radio frequencyback scatter principles or other sensing techniques as may beappropriate. Alternatively or in addition, an ATM may include one ormore programming devices which are operative to program the programmabletracking devices included on currency bills or sheets. In someembodiments and depending on the type of programmable tracking devices,the sensors and programming devices may be separate or a part of thesame device. In the exemplary embodiment shown in FIG. 2 such sensorsand programming devices may be incorporated with the validator device88. Alternatively one or more such devices may be separate and includedin appropriate areas of the machine. In some embodiments sensors andprogramming devices may operate to program the devices on sheets thatare moving through the machine while in others such devices may be readand/or programmed while in storage. Approaches taken will depend on theparticular types of devices used, the type of sheets involved and thetransaction functions carried out by the machine.

In some exemplary embodiments the ATM may include sensors for sensingwhether currency bills that are received by the machine includeprogrammable tracking devices. For bills that include such devices, theat least one processor in the machine may operate the at least oneprogramming device to include data in the memory associated with thetracking device on the bill that corresponds to the user and/or thetransaction. This may include for example data corresponding to the nameof the user, the user's account, the ATM in which the bill is received,the time and date of the transaction, the amount involved in thetransaction, the nature of the transaction and/or other data thatcorresponds to the transaction in which the bill is received. Of coursethese items are exemplary. Further in some embodiments the at least oneprocessor in the ATM may also operate to segregate bills that includeprogrammable tracking devices and store them in a particular storagearea. This storage area may be different than another storage area inthe machine used to store bills that do not include such programmabletracking devices. Thus for example the ATM may operate to store twentydollar bills that include programmable tracking devices in one storagearea while twenty dollar bills that do not include such devices arestored in a different area. In some embodiments the storage areas may bewithin containers that are removable from the interior of the ATM.

In addition in some exemplary embodiments the at least one sensor mayoperate as a reading device to read data that is included in the memoryassociated with the programmable tracking device on each bill proximateto the time that the bill is input to the machine. The at least oneprocessor in the machine may operate in accordance with its programmingto record and/or analyze this data for particular data of interest.Alternatively or in addition the ATM may transmit selected items of datafrom the bills to other computers for purposes of analysis. Suchanalysis may include information about transactions in which particularcurrency bills have previously been involved. Such information may beuseful in terms of tracking activities such as detecting moneylaundering, improper payments, tax evasion or other activities that maybe of interest. Of course these approaches are exemplary.

In some embodiments an ATM may include bill dispensing devices that arecapable of dispensing currency bills or other sheets that includeprogrammable tracking devices. In some embodiments such machines mayalso include dispensing devices that are also capable of dispensingcurrency bills that do not include programmable tracking devices. Suchembodiments may include ATMs that include bill receiving devices andcash dispensers as part of an integrated mechanism such as a cashrecycler. In other embodiments the ATM may only include mechanisms thatdispense bills from storage. In still other embodiments ATMs may includeseparate bill receiving devices. Of course various combinations of suchdevices may be included in the same or different ATMs.

Some embodiments may operate in accordance with the programmingassociated with at least one processor to cause data to be included onbills or other sheets that are dispensed from the machine. This may beaccomplished through operation of one or more programming devices in themachine. Such programming devices may operate, for example, to includedata on currency bills moving in the machine that are going to bedispensed to a particular user. The programming device may operate toinclude data in the programmable tracking devices that includeinformation that corresponds to the user receiving the bill and/or otherinformation. Such information may include for example, the recipient'sname, account number, the ATM at which the bill is received, thetransaction time and date, the transaction amount involved, thetransaction type or other information. Of course this approach isexemplary.

In some embodiments the at least one processor in the machine isoperative to provide outputs through the display of the ATM whichinclude indicia advising the user that they are receiving currency billsthat include programmable tracking devices. This may include for exampleoutputs which indicate that the bill that they are receiving includessuch tracking devices and/or the nature of the data which is beingprovided in memory on the bills. Of course in some embodiments suchinformation may be output through other devices on the machine such asthrough a speaker, headphone jack or other type of device through whichmessages may be perceived by a user.

In some embodiments the at least one processor may be programmed tooffer a user the option of not including any or certain data in theprogrammable tracking devices of bills or other sheets that are providedto the user. The user may provide one or more inputs to input devices onthe machine to indicate that they do not wish the bills or other sheetsthat are received to include any or at least some of this data. In caseswhere a user has provided such inputs, the at least one processoroperates so that such information is not included in the programmabletracking devices of the currency bills the user receives.

In still other embodiments the at least one processor may operate togive a user an option of receiving bills with or without suchprogrammable tracking devices. For example some users may prefer toreceive bills which do not include such programmable tracking devicesthereon. The at least one processor may provide outputs giving an ATMuser an option to provide an input to select to receive such bills. Byproviding at least one input the user may indicate to the machine thatthe bills to be dispensed should not include such programmable trackingdevices. The machine may then operate in accordance with its programmingto dispense only bills to that particular user that do not include suchprogrammable tracking devices. In some embodiments the at least oneprocessor may also operate to provide outputs to a user to indicate thatthere is an additional charge for receiving bills that do not includesuch programmable tracking devices. If a user provides inputs indicatingthat they wish to receive such bills despite the additional charge, theat least one processor will operate to assess a charge for the receiptof such bills in addition to the face value associated with the bills.Alternatively in some embodiments the at least one processor in themachine may operate to store information in the machine concerning theuser's request to receive bills without programmable tracking devices.Information about such transactions or the users involved therewith maybe communicated by the ATM to other computers for purposes of analysis.Such information may be used for example to identify possible illicitactivities. Of course these approaches are exemplary.

It should be understood that although the exemplary use of programmabletracking devices on sheets is used in connection with currency bills,the principles may also be used in connection with other parts of sheetsor items. These may include for example tickets, checks, scrip, gamingmaterials or other items that can be redeemed for goods or services. Forexample and without limitation, the principles described can be used inconjunction with gaming systems of the type described in U.S.Provisional Application Ser. No. 60/789,644 filed Apr. 5, 2006 thedisclosure of which is incorporated herein by reference.

It should be understood that the transactions described are exemplaryand additional types of transactions may be carried out throughoperation of various embodiments. In addition as previously discussed,mechanisms that are operative to both accept and dispense cash such asthose described in the incorporated disclosures may be utilized assubstitutes for, or in addition to, the mechanisms described herein soas to carry out transactions. Other types of transaction functiondevices may be included in some embodiments. For example as previouslydiscussed, embodiments may be operative to image and validate checks. Insuch cases it may be desirable for the machine to have the capability tocancel the check or destroy the check so there is no risk that the checkmay be later be stolen and used fraudulently. In some embodimentssuitable mechanisms may be provided for carrying out such functions. Inaddition it may be desirable in some embodiments to have the machineproduce bank checks, travelers' checks, tickets or other documents andsuitable mechanisms may be provided for producing such documents in theselected amounts. Further, in alternative embodiments features used bymerchants such as devices for accepting deposit bags, dispensing rolledcoin and other devices may be incorporated into an ATM or otherautomated banking machine having features described herein. As can alsobe appreciated, features of the exemplary ATM may also be used innumerous other types of automated banking machines.

Exemplary embodiments include light emitting devices 17, 31, 41, 43 and45. In the exemplary embodiment the light emitting devices arepositioned in areas on the user interface at locations associated withparticular transaction function devices. For example, light emittingdevice 31 is associated with the receipt printer 30 and light emittingdevice 17 is associated with the card reader 16. In the exemplaryembodiment the light emitting devices are in operative connection withthe one or more controllers in the machine. In addition, such devicesare capable of emitting light of selected colors at particular timesduring the transaction responsive to the operative condition of thetransaction function device of the ATM with which the light emittingdevice is associated.

In the exemplary embodiment the light emitting devices include an arrayof LEDs of different colors embedded on a flexible circuit. For example,FIG. 22 represents light emitting device 31. However, it should beunderstood that in the exemplary embodiment all the light emittingdevices are generally similar. Light emitting device 31 includes anarray of LEDs 304 connected through a circuit on a flexible substratesuch as a polymide film, for example, DuPont Kapton® material, andincludes a flexible connector portion 306. The flexible connectorterminates in an electrical connector 308. Electrical connector 308 isreleasably connectible to a driving circuit or other electrical circuitin the machine which operably connects to one or more controllers forpurposes of controlling the illumination of the light emitting device.

As shown in FIG. 23, in the exemplary embodiment the light emittingdevice includes three different color LEDs. These LEDs are red, greenand yellow, which are represented by “R,” “G,” and “Y” in the figures asshown. As represented in FIG. 23, in the exemplary embodiment the LEDsare in an array such that LEDs of only one color are vertically alignedalong a single line of the light emitting device. For example, as shownin FIG. 23, a line 310 comprises a line of vertically aligned red LEDs.As shown in FIG. 23, a line 312 is a line of only green LEDs, and a line314 of only yellow LEDs. As shown in FIG. 23, in the exemplaryembodiment the lines repeat so that there are five vertical lines ofeach color LED. It should be understood that while in the exemplaryembodiment the LEDs of each color are arranged in vertically alignedrelation; in other embodiments other arrangements such as horizontalalignment or other matrices of LEDs may be used. It should also beappreciated that although the LEDs are connected electrically in seriesas shown in FIG. 24, the electrical connections on the flexible circuitprovide for spaced vertically aligned pairs of LEDs of only one color.

As shown in FIG. 25, in the exemplary embodiment the light emittingdevices are supported in a flexible web. The web is thin in thepreferred embodiment, having a thickness of approximately 1.20millimeters. This facilitates the positioning of the light emittingdevices on the user interface. In the exemplary embodiment. LEDs whichare represented 316 and 318 are mounted on a base layer 320 includingthe circuit on a flexible substrate. An outer layer 322 which in theexemplary embodiment comprises a polyester layer overlies the LEDs. Aspacer 324 extends between the base layer and the outer layer. As bestshown in FIG. 23 multiple spacers may be used. In the exemplaryembodiment the spacers are positioned outboard of the LEDs and includeopenings 326 to facilitate positioning the light emitting devices on themachine. This may include, for example, extending pins, studs, orfastening devices through the openings so as to secure the lightemitting devices in the proper position. Further, in the exemplaryembodiment the release layer includes an underlying adhesive layer 328.The adhesive layer enables attaching of a light emitting device to aselected area within the machine. The adhesive layer is initiallyexposed for purposes of attaching the light emitting device by removalof an adhesive release layer 330 as shown in FIG. 25.

In an exemplary embodiment the light emitting devices are attached tocomponents of the machine with which they are associated. This may bedone, for example, by using modular construction for the transactionfunction devices within the machine and attaching the particular lightemitting device to the associated module. For example, FIG. 18 shows thecash accepting device 80 which is arranged as a modular device forpurposes of processing sheets that may be received in the machine. Inthe exemplary embodiment the associated light emitting device 41 ismounted in supporting connection with the module. The adjacent fasciaarea of the machine provides an opening through which the light emittingdevice may be viewed when it is in the operative position. In someembodiments the fascia of the machine may include a transparent ortranslucent material separating the light emitting device from theexterior of the machine. However, in other embodiments the lightemitting devices may be exposed on the exterior of the machine. Theattachment of the light emitting devices directly to the modularcomponents of the machine may facilitate assembly and service of themachine. Placing the light emitting device directly on the module of thetransaction function device with which it is associated, may reduce theamount of wiring and connectors needed for purposes of assembly andservice.

In the exemplary embodiment the multicolor light emitting devices areoperated under the control of one or more controllers in the machine.Each light emitting device is operated to emit light of a selected colorand/or in a selected manner responsive to the operative condition of anassociated transaction function device. For example, exemplary machinesmay be selectively programmable to emit a particular color lightresponsive to a given operative condition. For example, the lightemitting device adjacent to the card reader may emit green light when itis ready to receive the card of a user, and then change to a yellowlight after the card has been received therein. Alternatively or inaddition, lights of a different color may flash or alternate to reflectconditions of a particular device. Further, for example, in the event ofan improper action such as a user attempting to insert a card into thecard reader incorrectly, the controller may be programmed to have theassociated light emitting device emit red light or otherwise flash acolor of light so as to indicate to the user that they have donesomething improper. Similarly, if a particular transaction functiondevice is malfunctioning or not available, red light may be output.

In some exemplary embodiments the controller may be programmed so as toilluminate the light emitting devices to guide a user in operation ofthe machine. This may include, for example, illuminating or flashing aparticular colored light to indicate a required user activity at aparticular location on the machine. For example, at a particular time inthe transaction the controller may cause to be output on the display anindication to the customer that they are to take their receipt. When themachine has delivered the receipt, the controller may operate to causethe light emitting device 31 associated with the receipt delivery toilluminate, flash or otherwise indicate to the user that activity isrequired by the user in the area of the receipt delivery slot.

In some exemplary embodiments the controller may be programmed to causethe light emitting devices to selectively illuminate intermittently andfor a different duration depending on the operative condition of anassociated device. For example, if a user provides inputs so as torequest a cash-dispensing transaction, the light emitting device 43adjacent to the cash dispensing opening may illuminate in a yellowcondition as the machine operates internally to move bills toward thecash dispensing opening. Thereafter as the bills are pushed through theopening and presented to the user, the controller may cause the color ofthe light emitting device to change to green. In addition, thecontroller may cause the green light to flash so as to draw the user'sattention to the fact that the money is ready to be taken. Further, inan exemplary embodiment, if the user has not taken their cash after acertain time and the machine is programmed to retract it, the controllermay cause the light emitting device to flash or may operate so as toflash different colors in an alternating fashion so as to capture theattention of the user prior to the money being retracted.

In other embodiments, the colors emitted by the light emitting devicesmay be selectively programmed based on aesthetic reasons. For example,if the entity which operates the machine has particular trade dressinvolving certain colors the controller may be programmed to have thelight emitting devices correspond with that trade dress. Thus, forexample, if the particular entity's trade dress color is green, themachine may be programmed to utilize the green LEDs as lead-throughindicators in prompting the user in how to operate the machine. Likewiseif a different operating entity with a similar machine utilizes yellowas part of their trade dress scheme, the controller may be programmed toilluminate the yellow LEDs in the light emitting devices as thelead-through indicators.

It should further be understood that although the use of three colors oflight emitting devices is shown, this is exemplary and in otherembodiments additional types of light emitting devices may be provided.In addition it should be understood that although light emitting devicesin the exemplary embodiment are arranged so that only one color may beoutput from a given light emitting device at a given time, in otherembodiments provision may be made to illuminate multiple color LEDssimultaneously. In such arrangements, LEDs in primary colors may beincluded so as to achieve ranges of hue through color combinations. Thismay be done by illuminating multiple light emitting sourcessimultaneously and/or varying the intensity of such sources throughoperation of a controller so as to achieve various colors. This mayinclude, for example, providing for a gradual change in the hue of thelight emitting device in accordance with the status of the associatedtransaction function device. This may include, for example, providing anindication to the user of the status of the completion of a particulartask. Combinations of two or more colors may also be selectivelyproduced. It should also be understood that although LEDs are used asthe light source in the exemplary embodiment, in other embodiments ofthe invention other approaches may be used. It should be understood thatthe structures and operations described are exemplary and numerous otherstructures and methods may be used.

In the exemplary embodiment of ATM 10, provision is made to facilitate auser's operation of the machine and to minimize the risk of personsimproperly observing a user or their activities. Such undesirableactivities may include, for example, unauthorized persons observing theuser's input of their PIN number or other data. As shown in FIG. 26,fascia 12 of the exemplary embodiment includes a recessed area 332 inwhich the display, function keys, card reader and receipt outlet arepositioned. This recessed area 332 is illuminated by a light source 334.Light source 334 provides illumination generally in the downwarddirection so as to enable the user to more readily view the locations ofthe input and output devices on the fascia of the machine.

In the exemplary embodiment the fascia 12 includes a top panel portion336 which is positioned generally above the light source 334 and theuser interface of the machine. As represented in FIG. 26, the top panelportion includes a pair of convex mirrors 338, 340. The convex mirrors338, 340 are generally horizontally disposed and are positioned atopposed sides of the user interface.

As represented in FIG. 27, a user 342 operating the ATM 10 willgenerally have their body aligned with the user interface 15 of themachine. As a result, the user is generally enabled to view in theconvex mirrors an area behind the user generally indicated 343. The useris enabled to do this by looking in the mirrors 338 and 340 to theuser's left and right, respectively. By looking in these mirrors, theuser is enabled to generally see what is going on behind them as well asin a transverse direction from the area directly behind the user. Thismay enable the user to determine if one or more persons are in theirproximity as well as whether such persons may be attempting to observethe user or their inputs to the ATM. In some embodiments where the ATMis operated in an external environment, lighting sources may be providedin the area 343 to facilitate the user's observation of persons who maybe present therein.

It should be understood that the arrangement shown is exemplary and inother embodiments other mirror or observation arrangements may be used.In addition, in some embodiments provision may be made to maintain thecleanliness of the mirrors so as to reduce the risk that the user'sability to observe surrounding activities is impaired. These provisionsmay include, for example, automated devices which wipe the surface ofthe mirrors periodically. These may be external wiping devices or insome embodiments internal wiping devices. This may be accomplished, forexample, by having the convex mirrors be in supporting connection withone or more rotatable members that may be periodically rotated withinthe fascia by a motor or other moving device that operates responsive tothe ATM controller so as to expose a new external surface. Cleaningdevices on the interior of the fascia may operate to wipe contaminantsfrom the surface of the mirror as it passes internally such that furtherrotation exposes a clean mirror surface to the user. This may includefor example contact wiper blades that engage the surface of the mirror.Movement of the mirror surface such as rotation thereof in engagementwith the wiper blades may serve to remove accumulations of dirt on thereflective surface. In some embodiments the mirror surface may be partof a cylindrical body, and rotation of the body about a centrallongitudinal axis may provide wiping action as the mirror surface movespast stationary wipers engaged therewith. In some embodiments thestationary wipers may be comprised of resilient material and/or mayinclude movable mounting mechanisms so as to bias the wiper intoengagement with the movable mirror surface. In alternative embodiments areservoir of cleaning solution may be provided within or adjacent to themachine. A suitable pump or other device may be used to apply thecleaning solution to the mirror surface as it is moved relative to thewipers so as to facilitate the removal of dirt therefrom. Of coursethese approaches are merely exemplary and in other embodiments otherapproaches may be used.

In some embodiments the buildup of material on the mirror surface may bedetected to determine when there is a need for cleaning. This may bedone for example by providing a mirror that has some significant lighttransmission properties as well as light reflective properties in themanner of a half-silvered mirror. For example a radiation source andsensor may be positioned behind the mirror. In such embodimentsradiation emitted by the radiation source is partially reflected fromthe interior of the mirror surface and the magnitude of the reflectedradiation is sensed by the sensor. A buildup of dirt on the outersurface of the mirror changes the amount of radiation reflected from theinternal radiation source to the sensor. In some exemplary embodimentsthe buildup of dirt on the exterior mirror surface increases themagnitude of radiation reflected from the internal mirror surface. Thischange in the magnitude of reflected radiation is detected and used asthe basis for determining a need for cleaning the mirror. For exampleimmediately after cleaning the mirror the ATM controller or otherprocessor may cause the emitter to output radiation and the sensor tosense the magnitude of internally reflected radiation from an internalsurface of the mirror. This initial value is stored by the controller inone or more data stores. Thereafter on a periodic basis, for example ona timed basis or after each or a set number of transactions, the emittermay again output radiation and the level of reflected radiation sensed.The controller may then compare the then current level of reflectedradiation to the initial value.

In response to sensing a difference greater than the set amount, whichdifference corresponds to an unacceptable level of dirt built up on anexterior surface of the mirror, the controller operates to provide oneor more signals. The signals result in the mirrors being cleaned Suchsignals may include for example operating a device such as a motor orother mechanism so as to cause movement of the mirror to undergocleaning. Alternatively in some embodiments the controller may cause amessage to be sent to a remote servicer indicating a need for cleaningof the mirror surfaces on the fascia. In still other embodiments thecontroller may cause the ATM to operate to try to clean the mirrorsthrough the ATM's internal cleaning mechanism and then test thereflectance again after the attempted self cleaning. If the selfcleaning effort does not cause the reflectance value to reach the priorinitial value or within a programmed range (indicating perhaps that themirror has been spray painted) the controller is operative to cause amessage to be set to contact a remote servicer. Of course theseapproaches are merely exemplary and in other embodiments otherapproaches may be used.

In some other alternative embodiments the controller may sense for dirton a mirror through the use of mirrors or other reflective devices thatpass at least some significant amount of light therethrough from theexterior to the interior. One or more light sensors in operativeconnection with the machine controller are positioned behind the mirrorsurface. An external light sensor is positioned on the exterior of theATM to sense the level of ambient light. A controller is programmed todetermine an unacceptable level of accumulation of dirt on the mirrorbased on the level of external ambient light that is sensed as passingthrough the mirror. This may be done for example by sensing themagnitude of the signal from the ambient light sensor and comparing themagnitude of ambient light to the magnitude of light sensed as reachingthe sensor located behind the mirror. As can be appreciated when littleor no dirt is accumulated on the mirror surface, the greatest amount oflight will reach the sensor behind the mirror. As dirt accumulates, thelevel of light transmitted will decrease. If the magnitude of the lightsensed as passing through the mirror and reaching the sensor relative tothe level of ambient light declines to a preset ratio or other value,the controller may then operate in accordance with its programmedinstructions to operate the necessary device to self clean the mirror,generate signals so as to contact a servicer, or take other appropriateaction.

In further alternative embodiments one or more external ambient lightsensors may be in operative connection with the controller, and aninternal emitter and sensor behind a mirror surface that enables lightto pass therethrough may also be used. In such embodiments thecontroller may be programmed to analyze the amount of ambient light thatis expected to pass through the mirror and reach the sensor based on theambient light level. In such circumstances the controller can compensatefor the ambient light when sensing the level of reflected light from theinternal emitter. Such compensation may further help more accuratelydetect when there is a need for the mirror to be cleaned. Of course theparticular relationships and compensation levels will depend on theparticular mirror configuration. Alternatively or in addition in someexemplary embodiments, the controller may operate so as to sense thelevel of ambient radiation and the magnitude thereof that passes throughthe mirror to reach the sensor at a different time than when thecontroller operates the internal emitter and senses reflected radiation.The controller may be operative to compare these two separate values andthe relationship thereof and/or changes in reflectance and lighttransmissivity over time so as to determine when the mirror needs to becleaned. Of course these approaches are merely exemplary and in otherembodiments other approaches may be used.

In still other embodiments the mirrors may be operative only duringtransactions or portions thereof. This may be done for example byproviding mirrors that are operative only when a person is sensed asadjacent the machine or the machine is involved in conducting aparticular portion of a transaction. For example a sensor such as asonic sensor, radiation sensor, weight sensor or other suitable devicemay detect a user in proximity to the machine. Upon sensing the useradjacent the machine the controller may be operative to cause one ormore mirrors to be exposed externally on the fascia of the machine. Thismay be done for example by having movable members in supportingconnection with the mirror surfaces driven by motors or other suitablemoving devices that are in operative connection with the controllers.Upon sensing a user adjacent the machine the controller is operative tocause the motors or other moving devices to cause the mirrors to moveinto an operative position so a user can view the area behind them.

For example in some embodiments the reflective surfaces which comprisethe mirror may be in supporting connection with a rotatable member. Therotatable member may be rotated when the customer is present at themachine so that the reflective surface is positioned so as to providethe user with a view of the area behind them. Further, when the customeris sensed as leaving the area of the ATM, such departure of the user issensed and the controller in response thereto is operative to cause themembers that include the reflected surfaces to move so that thereflector surfaces are no longer exposed. Such an approach may providean advantage in that the mirror surfaces are exposed to the elementsonly during the times when transactions are occurring and therefore areless likely to accumulate dirt as quickly. In addition, in someembodiments wipers or other suitable cleaning devices may be providedadjacent to the reflective surfaces so that as the reflective surfacesmove the surfaces are wiped and cleaned so as to remain relatively dirtfree.

Although in some embodiments the reflective surfaces may move into theoperative position for a customer responsive to sensing a user adjacentto the machine, in other embodiments other approaches may be used. Thesemay include for example moving the mirror surfaces to the operativeposition only in response to certain actions or certain transactiontypes being conducted by the user at the machine. Alternatively or inaddition the mirrors may be moved to the operative position only inresponse to other conditions such as ambient lighting conditions, thetime of day and/or the sensing of persons or objects entering an areabehind the user in which persons or objects are sensed. Alternatively orin addition the controller may be programmed and appropriate sensors maybe provided to move the mirrors to the operative position based on thenature of the use being made by the user of the ATM. For example in anATM that is intended for both drive up and walk up use, appropriatesensors may be positioned so as to sense whether the user is positionedin a vehicle or has approached the machine on foot. This may be done forexample through proximity sensors, magnetic sensors, weight sensors orother suitable sensors. The controller may be programmed to make adetermination based on one or more sensor inputs whether the user is ina vehicle or is on foot. In situations where the user is determined tobe in a vehicle the deployment of the mirrors to the operative positionmay be deemed unnecessary because the vehicle may serve to block accessby unauthorized users to viewing the inputs that the user makes to themachine. Alternatively if the user is determined to have approached themachine on foot, the controller may be operative to deploy the mirrorsto the operative position so as to assure that the user can view thearea behind them in which unauthorized persons may be attempting to viewinputs to the machine.

In still other embodiments, alternative or additional provisions may bemade to further help to prevent the observation of inputs by users tothe machine. For example in some embodiments the machine fascia may beprovided with lighting that is directed rearward from the fascia outsideof the line of sight of the user. Such rearward directed lighting, whenactivated, may operate to obscure the view of unauthorized persons ordevices attempting to observe inputs by the user to a machine. Suchrearward directed lighting may be selectively operative when a user issensed as adjacent to the machine so as to reduce the risk of theinterception of the user inputs and/or to provide lighting in the areabehind the user. In other embodiments the controller may be programmedso as to be operative to initiate the rearward directed lighting onlyduring certain portions of the transaction where the user is conductingcertain activities. For example the controller may be programmed so asto activate the lighting when the user is providing an input of a PINnumber which unauthorized persons may wish to intercept. Further in someembodiments the rearward directed lighting may be activated only atthose times that the mirrors are moved into the activated position.Alternatively or in addition the lighting devices may be mounted insupporting connection with the mechanisms associated with the mirrorstructures. Further provision may be made in some cases so as to providemechanisms for cleaning the lighting devices as they are moved into theoperative position. Of course these approaches are exemplary and inother embodiments other approaches may be used. Further, the principlesdiscussed may be used with other types of automated banking machines andin other circumstances other than those described in connection with theexemplary embodiment.

FIGS. 28-31 are directed to yet other exemplary embodiments to furtherhelp to prevent the observation of inputs by users to the machine byunauthorized persons. As shown in FIG. 28 a user input device which inthe exemplary embodiment comprises a keypad 18 comprising a plurality ofkeys, may be covered by a concealment device generally denoted 350. Asshown in FIG. 29, the concealment device 350 may include a body which isalternatively referred to as a casing 354, including top cover 358,first and second side walls 360, 362, respectively, and back wall 366which bound an interior area. Elements of the exemplary casing 354extend in generally surrounding relation of the keypad and in thisembodiment cooperate to form a viewing portal 370. A viewing portalcomprises an area in which a user can view the input device and theactuation thereof by the user such as by a user's fingers which arealternatively referred to herein as digits. In the exemplary embodimentshown viewing portal 370 is formed by a gap between the top cover 358and back wall 366, although various other approaches may be used. Forexample, the top cover 358 may abut back wall 366 and viewing portal 370may be cut out of the top cover 358. Viewing portal 370 mayalternatively be an open slot, or it maybe formed of transparentmaterial. Alternatively, the viewing portal may comprise othercombinations for indirect viewing and may include for example a cameraor other image device in the casing, and a display positioned in alocation for viewing only from a point of view of the machine user. Insome embodiments the display may be the display of the ATM, such asdisplay 24. Alternatively the viewing portal may comprise one or moredisplays supported on the casing 354, the ATM fascia 12 or otherlocation that limits viewing of the inputs being made only to themachine user.

The elements of casing 354 cooperate to define an interior area 374. Theuser input device or keypad 18 may be accessible to a user through handentry slot 376 which is bounded by the casing. The user in thisembodiment is enabled to extend one or several fingers and a portion oftheir hand in the slot to actuate the keys of the keypad.

With reference to FIG. 30, concealment device 350 includes an indirectviewing mechanism generally denoted 378. In this exemplary embodiment,the indirect viewing mechanism 378 includes reflecting surfaces withinthe interior area. A first mirror 380 is disposed on an interior surfaceof the top cover 358. A second mirror 382 may be positioned on aninterior surface of back wall 366. In the exemplary embodiment, firstmirror 380 is operable to reflect an image of user input device; in thisexample keypad 18 toward the back wall 366. Second mirror 382 isoperable to reflect that image so that it can be viewed through theviewing portal 370. The viewing portal 370 is arranged to allow a userto view the reflected image from a viewing position in the user's lineof sight 386. Thus indirect viewing mechanism 378 utilizes theproperties of reflected light in order to allow a user to indirectlyview inputs as they are being made by the user's fingers to keypad 18.The double reflection of the image of the keypad 18 presents an image incorrect orientation to the user.

The arrangement and user's required body position necessary to extend ahand through the opening to actuate the keypad may prevent unwantedviewing of the user inputs from a position directly behind the user andthe casing 354 operates to cut down on sight lines from viewpoints onthe top and sides. In this exemplary embodiment, input device 18 cannotbe readily viewed by a person other than one having a point of view ofthe user of the banking machine, thus enhancing the security of anyinput made.

A user may thus use the automated banking machine with greaterconfidence that various inputs, including a PIN, may not be readilyviewed by another. Also, the exemplary embodiments of the concealmentdevice 350 prevent unauthorized devices that may be positioned to viewthe ATM fascia such as cameras, from viewing the input of the user'sPIN.

In yet another exemplary embodiment, an exemplary casing 354 isselectively positionable with respect to the user input device 18between a covered position, as illustrated in FIG. 27, and an uncoveredposition, as illustrated in FIG. 31. The casing 354 or a portion thereofmay be mounted in supporting connection with the fascia 12 via one ormore hinges 390 or other supports which enable movement thereof. In thisexemplary embodiment, hinge 390 extends between first side wall 360 andfascia 12 to allow selective positioning of casing 354. Thus, in thisembodiment if a user believes that the added security of the concealmentdevice is unnecessary under the circumstances, the casing 354 can bemoved from its covered position to an uncovered position to allow directviewing of the keypad 18.

In alternative embodiments the device may include a movable cover forsecurely providing access to the input device. For example the top cover358 may be mounted in movable supporting connection with the casing. Thetop cover may be movable to an open position such that the input devicebecomes more accessible when the cover is moved from a closed positionto an open position. In some embodiments based on the mounting, the sizeof the opening may be increased as the movable cover is moved from theclosed position to the open position. In some embodiments an ATM usermay be able to open and close the cover or other enclosure as they deemfit. In alternative embodiments the casing may be held closed by a lockor other latching mechanism. The lock or latching mechanism may beopened by a servicer or other authorized person for servicing such ascleaning or other maintenance functions. Of course these approaches areexemplary and in other embodiments other approaches may be used.

In yet another exemplary embodiment, an exemplary concealment device 350may include a lighting mechanism such as light 394, operable toilluminate interior area 374. The illustrated positioning of thelighting mechanism is merely exemplary and in other embodiments, otherapproaches may be used. For example, the lighting mechanism may beincorporated into the keypad 18, or may be mounted on the interior ofthe top cover 358. For example, the keypad may include a backlightingmechanism such that the keys are illuminated. Such an illuminationmechanism may be combined with a mechanism that detects unauthorizeddevices that are intended to intercept a user's inputs. Such a system isshown in U.S. patent application Ser. No. 10/832,960 filed Apr. 27, 2004which is incorporated herein by reference as if fully set forth herein.Alternatively or in addition, embodiments may include backlighting ofthe input device and lighting of the interior area from a directionother than that of the face of the input device. Such apparatus may helpin viewing the user's fingers in actuating the keys of the keypad. Insome alternative embodiments lights of difference colors may be used tofurther aid in viewing the input device and the user's fingers. Forexample in some embodiments the keypad may be backlit in one color whilea light of a different color within the casing primarily illuminates theuser's fingers. This may make it easier to view the user's fingers inrelation to the keys of the keypad. Of course this approach is exemplaryof many that may be used.

In still other embodiments provisions may be made to facilitate viewingthe casing. For example in some embodiments, particularly those designedfor use in an outdoor environment, moisture may tend to condense withinthe interior area of the casing. In some embodiments devices forminimizing condensation may be provided. Such devices may include forexample, an air movement device such as a fan schematically indicated396. The fan may be operative responsive to a controller in the ATM orother device to cause air movement in the casing and minimizecondensation of moisture. In some embodiments a heater 398 may beprovided to heat air within the casing. The heater may be operativeresponsive to the controller in the ATM or other controller to heat theair within the casing so as to reduce the risk of condensation.

In some embodiments sensors may be provided in or adjacent to the casingto detect conditions that likely result in condensation. These mayinclude temperature and/or humidity sensors that are used to senseconditions that result in condensation. In response to such conditionsthe heater and/or the fan are caused to operate. Alternatively or inaddition, sensor systems of the type previously discussed in connectionwith the detection of the need to clean the mirrors 338 and 340 may beused in connection with the reflective surfaces within the casing. Forexample, such approaches may be used for detecting condensation on thesurfaces and may cause a controller to turn on and off the fan and/orheater as appropriate. Alternatively or in addition, signals fromtemperature and/or humidity sensors may also be used in the programsexecuted by the controller in deciding what actions to take.Alternatively in some embodiments, provision may be made for signalingthe need for cleaning the reflective surfaces in a manner similar tothat discussed in connection with the mirrors 338 and 340. Alternativelyor in addition, provisions may be made in some embodiments for providingfor automated cleaning thereof. It should further be understood thatalthough the fan and heater are schematically shown in the casing, insome embodiments such devices may be positioned within the housing ofthe ATM and suitable fluid conduits provided to achieve air flow and/orheating within the interior area of the casing. Of course theseapproaches are exemplary and in other embodiments other approaches maybe used.

In some embodiments sensors may be provided to detect attempts toinstall unauthorized input interception devices. These may include forexample, sensors that sense radiation properties within the interior ofthe casing so as to detect installation of an unauthorized device fordetecting the pressing of keys. Alternatively devices for impartingvibration to the fascia and/or casing and sensing changes in vibrationproperties may be used to detect the presence of an unauthorized device.Alternatively or in addition, sensors which detect changes in levels orfluctuations in radio frequencies may be installed to detect theinstallation of a radio transmitter associated with an unauthorizedinput interception device. Approaches described may also be of the typedisclosed in the incorporated disclosure of U.S. application Ser. No.10/832,960. Controllers in operative connection with such sensors whichdetect unauthorized input interception devices may be operative tonotify a remote entity, modify operation of the ATM, initiatecountermeasures to prevent input interception, invalidate user cardsand/or cause the ATM to cease operation. Of course these approaches areexemplary and in other embodiments other approaches may be used.

In alternative embodiments other approaches may be used to minimizeinterception of inputs by unauthorized persons. For example in someembodiments the reflective surfaces may be configured such that a user'seyes must be positioned in a particular location to readily observe thekeypad and fingers. As a result, an unauthorized person or deviceattempting to observe user inputs in a position that is remote or evenrelatively close to a user's position cannot actually observe theinputs. This might be done for example by using contoured mirrorsurfaces that enable a clear image only from a point of view in aparticular location. In alternative embodiments the reflective surfacesand/or the casing may be made to be movable by the user. This could bedone through a movable mounting of the casing in supporting connectionwith the fascia of the ATM such that the user can precisely position thespot at which the inputs may be readily observed. In some alternativeembodiments the keypad or other input device may also be made movablesuch that the user can precisely position the portal for viewing. Suchapproaches may also make the ATM more readily suitable for use by bothleft and right hand users as well as persons of varying heights. Ofcourse, these approaches are exemplary of many that may be used

Of course as previously discussed, some embodiments may have an imagingdevice in the casing and may provide outputs for viewing on one or moredisplays. In some embodiments provision may be made to enable a userthrough hand and/or finger movements to adjust the position of one ormore display screens or the position of the output image within a fieldof view such as on the ATM display. For example, a display screen may bepositioned on the casing, and may be movable with or relative to thecasing to a desired position by the user to minimize the risk of inputobservation. Alternatively if an output though the ATM display is used,the user may position a frame showing the user's fingers and inputdevice selectively on the display in a way that assures it is blockedfrom viewing by others.

In some embodiments the display screen may be operative only duringselected time periods during transactions when inputs to the inputdevice are possible or required. For example, an image of the keypad andthe user's fingers may appear only in a portion of the ATM displayduring a transaction when the machine is in condition to receiveconfidential inputs. For example, the image may be output when a user isrequired to input a personal identification number (PIN). At other timesthe image of the input device may not be presented. Alternatively one ormore sensors may sense the introduction of the user's fingers into theinterior area of the casing and cause a controller in the ATM to providescreen outputs. This may be appropriate for example in situations wherea user enters various inputs such as a PIN, amounts or otherinstructions at various times during various transactions.

Further, in some embodiments an ATM controller may be programmed tosense that a user is using voice guidance features for operating theATM. This might be done for operation of the ATM by a visually impairedperson. In such circumstances the ATM may sense that a user hasconnected headphones to a headphone jack on the ATM to receive audioinstructions. In such embodiments the controller may operate to shut offor restrict viewing through the viewing device. This may include nothaving the image of the input device appear on the ATM display or otherscreen. Alternatively in other embodiments the controller may notactuate the lights that enable viewing the input device in the casing.Of course difference approaches may be used depending on the particularembodiment.

It should be understood that while the exemplary embodiment is discussedas being in connection with an ATM keypad, other embodiments may be usedwith other types of banking machine input devices.

FIGS. 32 and 33 disclose an alternative embodiment that prevents theunauthorized viewing of customer inputs to a keypad of an ATM or otherautomated banking machine. This exemplary embodiment includes a cover400. Cover 400 overlies at least a portion of all of the keys 402 of akeypad 404. Cover 400 of this exemplary embodiment includes a topportion 406. Cover 400 also includes a pair of tapered side wallportions 408. Top portion 406 and wall portions 408 bound an opening410. Opening 410 enables users to extend their digits through theopening generally in the direction of arrow M so as to enable a user toengage all of the key engaging surfaces of the keys which make up thekeypad.

In this exemplary embodiment the cover 400 is attached to an ATM fascia412. Fascia 412 includes a rectangular depression or recess 414. Thetapered wall portions 408 terminate in inturned flange portions 416. Inthe exemplary embodiment the flange portions are sized so as to extendin corresponding shaped recesses or pockets within the recess 414 of thefascia. In the exemplary embodiment the inturned flange portions 416engage the fascia in the pockets and are held in fixed engagementtherewith through adhesive or other fastening devices. As can beappreciated from FIGS. 32 and 33, the exemplary embodiment provides forthe tapered side walls 408 to extend upward from the recess 414 in thefascia in close abutting engagement with the generally verticallyextending walls of the fascia which bound the recess. This helps tominimize the risk of vandalism in which the cover 400 is pried off thefascia.

In the exemplary embodiment the top portion 406 is generally tapered sothat the top portion extends closer to the upper surface of the keyswhich make up the keypad with increasing distance from the opening 410.It should be understood however that the inner surface of the topportion remains sufficiently disposed from the keys so as to providesufficient digit access thereto. Also in the exemplary embodiment thetapered side wall portions 408 taper inwardly with increasing distancefrom the surface of the keys and join with the top portion. In theexemplary embodiment the cover 400 is integrally formed of suitableplastic or other durable material. Of course in other embodiments otherapproaches may be used.

The exemplary cover 400 is constructed such that the tapered side wallportions 408 are comprised of generally nontransparent material whilethe top portion 406 is comprised of transparent material. This helps toassure that a user having a point of view of that of a user of themachine is able to view the keypad and the engagement of his or herdigits with the keys through the top portion. Persons attempting tointercept the inputs of the machine user generally do not have theability to intercept visual signals near the point of view of themachine user and are blocked from viewing the manual digit engagement ofthe keys by the generally nontransparent sidewalls 408.

In this exemplary embodiment cover 400 includes on the top portion 406 aplurality of elongated outward extending projections 418. The outwardextending projections which are alternatively referred to herein as ribsextend generally along the direction of Arrow M. Extending between theprojections 418 are visual openings 420. In the exemplary embodimentvisual openings also extend on the top portion outboard of the furthestprojection on each lateral side to the point where the top portionengages the tapered side wall portion. The visual openings provide forgenerally undistorted viewing of the keypad and the manual digitengagement of the keys by the user through the top portion. Theelongated projections 418 operate to distort the view of the keys byunauthorized persons not having the point of view of the machine user.Thus in the exemplary embodiment even if an unauthorized person is ableto place a camera or other viewing device in reasonable proximity to thetop portion of the cover, the requirement to have the viewpoint of thecamera offset from the point of view of the user results in theprojections preventing the camera from having a clear view of the user'sinputs. Of course this approach is exemplary and in other embodimentsother approaches may be used.

In some embodiments of the cover 400 the elongated projections 418 maybe configured so as to prevent the viewing therethrough even fromcertain points of view of a machine user. In such embodiments themachine user's view of the keypad from a narrow range of positions issufficient through the visual openings 420 to provide the necessaryinputs. In other embodiments the projections 418 may be configured sothat moderately distorted viewing is possible therethrough from thepoint of view of the machine user. In such cases the distortion from thepoint of view of the user is limited, while viewing from a viewpointangularly disposed from the machine user's point of view, issufficiently distorted so that it is not reasonably possible todetermine the user's manual inputs.

In alternative embodiments rather than having projections that extendoutward from the top portion of the cover, the projections may extendinwardly so as to provide sufficient distortion in viewing from otherthan a user's point of view to reduce the risk of inputs beingintercepted. In still other embodiments the projections may extend invarious directions and in different ways as is appropriate to achieve areduction in the risk of unauthorized viewing. In still otherembodiments projections may be included on covers so that although theentire cover is comprised of transparent materials, the projections areconfigured to make viewing through the cover reasonably impossible fromall but the desired point of view of the authorized machine user. Someembodiments may include features such as those previously discussed, tofacilitate viewing by the authorized user. This may include for example,providing lighting within the cover so as to facilitate viewing by theuser. Such lighting may include the provision of fiber optic strands orother suitable light guides to facilitate the output of light of asuitable type so as to enable the provision of inputs by a user.Similarly fiber optic outputs may be used to emit light from surfaces ofthe cover that help to obscure viewing of user inputs from viewpointsother than the user's point of view. This may be done selectively and attimes during transactions when the machine is in a state to receive userinputs. This may be accomplished by at least one processor in themachine controlling the output from one or more light sources.

Further alternative embodiments may also include provisions fordetecting and minimizing the risk of condensation within the cover. Thismay include for example, providing sensors for detecting condensationeither inside or outside the cover. This may include for example sensorswhich sense the transmission of the light through the cover or whichdirectly detect the presence of moisture. Such sensors may be inoperative connection with one or more processors within the machine sothat the machine can take appropriate steps to eliminate the problemand/or if the problem cannot be detected as having been remedied afterthe machine takes action, to cause the machine to notify an appropriateentity such as a service company. For example in some embodimentsprovision may be made for the machine to cause a flow of air to bedirected beneath the cover on a periodic or continuous basis. Such airflow may be controlled so as to minimize the risk of condensation orother conditions which obscure viewing through the cover. It shouldfurther be understood that the techniques described in connection withdetecting the accumulation of dirt on viewing mirrors may also beapplied to assuring the sufficient clarity of the top portion of thecover so as to enable operation of the machine by users. Of course theseapproaches are merely exemplary and in other embodiments otherapproaches may be used.

FIG. 39 shows an alternative cover 422. Cover 422 is generallyconstructed and operated in a manner similar to cover 400 except asspecifically discussed. Cover 422 of this exemplary embodiment has a topportion 424 and sidewall portions 426 comprised of generallynontransparent material. In this exemplary embodiment top portion 424includes a plurality of parallel slots 428 which serve as visualopenings. In this embodiment the visual openings 428 are openingsthrough the top portion of the cover that are sized and spaced such thata user in a limited range of viewing positions at the user interface ofthe banking machine is enabled to see their manual digit engagement withthe keys of the keypad underlying the cover through the openings. Theexemplary openings are configured such that an unauthorized person orviewing device that is angularly disposed from the point of view of themachine user, is unable to adequately view the keys engaged by a userwhen performing a transaction. For example in this exemplary embodimentunauthorized users attempting to intercept inputs from a viewpoint tothe side of the machine user do not have sufficient visual access to thekeys to see what keys are being engaged. However, the openings willenable the machine user to see what keys the user is pressing.

Of course it should be understood that this approach is exemplary and inother embodiments other approaches may be used. This may include forexample, providing visual openings of various dimensions, configurationsand sizes in lieu of the elongated openings shown. As can be appreciatedarrangements of visual openings of various shapes and sizes may providea machine user within a suitable range of points of view with anadequate view of the keys of the keypad while obscuring viewing byunauthorized users. As can be appreciated in exemplary embodiments theability of the covers to require that a user position their head andeyes in a particular area to view digit engagement with the keys, urgesthe machine user to position their body at the machine in a way thatfurther blocks unauthorized observation of the user's inputs.

In alternative embodiments other approaches to producing the visualopenings may be used. This may include for example, embedding materialswithin the cover so that the cover includes certain areas that aretransparent and other areas that block viewing from a viewpoint disposedfrom the point of view of a user. Alternatively in some embodiments aplurality of structures, markings or other suitable devices may beincluded within the cover so as to only enable viewing therethrough froma permitted direction or location. This may include for example,achieving a light polarizing effect. Such effect may enable the personhaving the point of view of a machine user to be able to readily seethrough the top portion of the cover, while a device or person viewingthe cover from an angle of incidence beyond the narrow range of a user'spoint of view is unable to see through the cover. In still otherembodiments covers may implement electro-optic features to control thepoint of view from which user inputs can be detected. This may includefor example including liquid crystal materials in at least a portion ofthe cover. The opaque or visible properties of the cover with respect tothe field of view of the user may be controlled responsive to operationof at least one processor in the machine. For example the liquid crystalmaterial may be activated in a selected area of the cover to enableviewing therethrough. On other areas the liquid crystal material remainsopaque. In still other embodiments electro-optic properties such asproviding a polarizing effect or Fresnel lens effect may be achieved tolimit observation of the keys to a field of view of the user. In stillother embodiments liquid crystal material within the cover may be usedto provide a Fresnel lens effect which achieves magnification of thekeys for a user. This may be selectively controlled through operation ofa processor in the machine. Changes in magnification or focus effectsachieved with the liquid crystal may be based on the user inputs to theATM or data stored remotely of the ATM which is operative to determinewhen a particular user or user type is identified as operating themachine. For example if a user is sensed as connecting headphones to themachine so as to operate the machine in response to audio outputs, theat least one processor may operate to obscure all viewing of the keypadthrough the cover. Alternatively if a machine user indicates or isotherwise identified as one who requires magnification, the Fresnel lensproperties may be used to provide magnification. Of course theseapproaches are exemplary and in other embodiments other approaches maybe used.

FIGS. 37 and 38 show yet another alternative exemplary keypad cover 430as well as an exemplary method used to install the cover on a fascia 432of an automated banking machine. Cover 430 of the exemplary embodimentis generally similar in construction to cover 422 except that cover 430includes one relatively large opening 434 in the top portion thereof. Asrepresented in FIG. 38 opening 434 when the cover is installed overliesat least some portion of the keys 436 of the keypad 438. However, asshown in FIG. 38 a user is still enabled to view all of the keys fromthe point of view of a user operating the user interface of the machine.

A top portion 440 of the cover bounds the opening 434. Tapered sidewallportions 442 extend outward from the top portion as is the case with thepreviously described embodiments. The tapered sidewall portions eachterminate in inturned flange portions 444.

In the exemplary embodiment the fascia 432 includes a generallyrectangular recess 446. The recess is bounded by generally verticallyextending fascia walls 448 on each transverse side of the recess 446.The vertically extending walls extend from an outer fascia wall surface447 to the fascia face within the recess. Extending between the keypad438 and the fascia walls 448 on the fascia are a pair of pockets 450. Inthe exemplary embodiment the pockets 450 are recessed within the fasciaface and extend below a plane in which the upper surfaces of the keys436 generally extend when they are not being depressed. The exemplarypockets are sized so that the inturned flange portions 444 are acceptedinto the pockets when the cover is installed.

As can be appreciated from FIGS. 37 and 38, in the exemplary embodimentwhen the cover 430 is to be installed, the cover is moved relative tothe fascia such that the flange portions 444 are engaged in the pockets450. The flange portions 444 serve as engaging portions which areaccepted in the pockets. In the exemplary embodiment the cover 430 isheld in engagement with the fascia through adhesive which is applied inthe pockets. This adhesive may be applied on media such as a suitabletape based material or alternatively as a liquid or solid adhesivematerial. As can be appreciated the adhesive holds the cover 430positioned as shown in FIG. 38 in engaged relation with the fascia. Inthe exemplary embodiment the size of the flange portions and the pocketswhich are engaged hold the cover and fascia together are sized so as tominimize the risk of the cover being pulled off due to vandalism.Further the proximity of the sidewall portions 442 to the fascia walls448 of the exemplary embodiment minimize the risk of an unauthorizedperson prying the cover off the fascia. However, in the exemplaryembodiment if sufficient force is applied to the cover to tear it offthe fascia, the pockets are sized so as to allow the cover to be removedwithout causing permanent damage to the fascia. This is achieved in anexemplary embodiment by controlling the area of adhesive contact to thearea of the pockets and the strength of the adhesive. This approachassures that the adhesive will release before the cover or the fasciabreaks. Alternatively in some embodiments a similar result may beaccomplished by providing weaker areas in the cover at or above each ofthe flange portions. These weaker areas may serve as frangible portionsthat break in responsive to applied force before other areas release orbreak. In some embodiments the point of breakage may be configured sothat a new cover can be installed without removal of the prior flangeportions. For example, the flange portions of the replacement cover maybe attached to the flange portions of the cover that has otherwise beentom away. As a result a new cover can be installed through the methodpreviously discussed, generally without the need to make other repairsto the fascia of the banking machine.

Of course it should be understood that these approaches are exemplaryand in other embodiments other approaches may be used.

FIGS. 34 through 36 and 40 show yet another alternative embodiment of anapparatus for reducing the risk of interception of a user's confidentialinputs through a keypad of an ATM. In this embodiment an automatedbanking machine includes a fascia 452. The fascia 452 includes agenerally rectangular recess 454 which is bounded laterally by a pair offascia sidewalls 456. The keypad 458 which includes a plurality of keys460, is positioned so as to be manually accessible in the recess. As isthe case with the previously described embodiment, users of theautomated banking machine are enabled to provide inputs through manualdigit engagement with the keys of the keypad. The keys of the keypadgenerally extend within a plane which extends within the recess of thefascia.

This exemplary embodiment comprises a pair of movable panels 462 and464. The panels are disposed on opposed lateral sides of the keypad 458.Each of the panels is mounted in supported connection with the machinethrough a hinge connection (not separately shown). The hinge connectionof the exemplary embodiment comprises a structure which enables eachrespective panel to move rotationally about an axis of the hingeconnection adjacent to the area where the panel is connected to thefascia.

In the exemplary embodiment panels 462 and 464 are enabled to be rotatedabout the hinge connection between a first position and a secondposition. The first position which is shown in FIGS. 35 and 36 is aposition in which the panels extend generally upwardly relative to thefascia so as to prevent viewing of a user's inputs through the keys,from a position other than the point of view of the machine user. In theexemplary embodiment shown in FIGS. 35 and 36 in the first position ofthe panels, the panels also generally overlie some of the keys of thekeypad. In this way the panels are enabled to restrict viewing of thekeypad by unauthorized persons while at the same time enabling the userto view the keypad so as to provide their necessary manual inputs suchas a PIN number. It should be understood however that although theexemplary embodiment shows the panels extending at an angle in overlyingrelation of at least some of the keys of the keypad, other embodimentsmay provide for the panels to be in a different position so as torestrict viewing. This may include for example the panels moving to aposition generally perpendicular of the fascia and the plane in whichthe keys of the keypad extend. In some embodiments movement of thepanels to a position generally perpendicular to the keys may besufficient for purposes of restricting unwanted viewing of the keypad.

In the exemplary embodiment the panels 462 and 464 are enabled to moveto a second position shown in FIG. 34. In the position shown in FIG. 34the panels do not overlie the keypad and are not generally operative torestrict viewing from a wider range of viewpoints that are outside theviewpoint of a machine user operating the machine. The panels may bepositioned in the second position for purposes of a user providingnon-confidential inputs through the keypad such as amount data ortransaction selection data.

In some exemplary embodiments, panels 462 and 464 are manually movableby a user at the banking machine. In such embodiments a user who isabout to input confidential data may move one or both of the panels fromthe first position to the second position so as to reduce the risk ofunauthorized observation of the user's input of confidential data suchas their PIN number. Thereafter when the user has completed the PINnumber input the user may manually move the panels to the secondposition. Alternatively in this embodiment if the user is concerned thata person may be attempting to observe their inputs from a particularside of the machine, the user may elect to move only one of the panelsto the first position so as to obscure viewing from viewpoints on thatparticular side. Alternatively or in addition the ATM user may movetheir point of view to a side away from the panel in the first position.In this way the user can control the panels and reduce the risk ofobservation by other individuals. Of course in this embodiment the usermay also determine that no one is nearby and they wish to leave thepanels positioned in the second position at all times regardless of thenature of the inputs being provided through the keypad.

In exemplary embodiments the panels 462 and 464 may be held in theposition in which they are manually placed through the effect ofgravity. Alternatively in other embodiments the panels may bespring-loaded so that for example they are held by gravity in the firstposition but when a user moves them rotationally beyond a particularangle, they are biased toward the second position. Alternatively each ofthe panels may be biased toward the first position as well as toward thesecond position depending on the angle to which they are manually moved.Various approaches may be taken depending on the nature of the system.

In some embodiments the panels and/or the structures which comprise thehinge connection may be attached to the fascia of the machine byadhesive or other materials that resist the removal of the panels, butare nonetheless frangible so that once excessive force is applied thepanels break away, reducing the chance of more substantial damage to thefascia. This can be done for example in the manner previously discussedby providing a hinged connection or other suitable connection through aflange portion which is held by adhesive in appropriately sized pocketsof the recess of the fascia. Thus if the machine is subject to vandalismand a panel is tom off, a replacement panel may be readily applied.Further it should be understood that while the exemplary embodiment hasrectangular panels of the shape shown, other embodiments may includeother shaped panels or mounting mechanisms.

While the exemplary embodiment may include manually movable panels,other embodiments may include panels in operative connection with drivesor other movement devices so as to automatically move the panels atappropriate times during transactions. Such a system is schematicallyrepresented in FIG. 40. In this system panel 462 is shown in operativeconnection with a drive 466 and panel 464 is shown in operativeconnection with a drive 467. Of course it should be understood thatdrives 466 and 467 may comprise suitable movement devices such asmotors, solenoids, actuators or other movement devices. Further suchdrives may include transmission mechanisms which limit the applicationof force to the panels and reduce the risk of damage in the event offorced manual movement of the panels or if the panels are prevented frommoving due to an obstruction. Various suitable force-limitingtransmission mechanisms may be devised that are suitable for theparticular embodiment by those having skill in the art.

In the exemplary embodiment at least one processor operating in theautomated banking machine may operate in accordance with its programmingto determine when the machine is ready to receive a confidential inputfrom a user. This may include for example the at least one processordetermining that the machine has reached the point in its operationwhere the machine is in condition to receive the input of a PIN from auser. Responsive to this determination the at least one processor isoperative to cause the drives 466, 467 to move the panels 462, 464 intothe raised first position. In this raised first position, the panels areoperative to generally block viewing of inputs to the keypad from aviewpoint other than the point of view of the machine user. Likewise insome exemplary embodiments the at least one processor may be operativeto determine when a machine user has completed the input of theconfidential data such as the PIN and to cause the drives to then movethe panels to the second position. Of course this approach is exemplary.

It should be understood that in some embodiments the at least oneprocessor may be operative to move the panels to the first position soas to restrict viewing, not only for the input of PIN data but alsounder other circumstances where confidential inputs may be required.Further in some alternative embodiments the at least one processor mayoperate only to provide certain movement for the panels. For example insome embodiments rather than having the panels moved to the firstposition by the drive, the user may be able to manually move one or bothpanels to the first position. After the at least one processordetermines that the user has completed providing confidential inputs orthat the user has completed a transaction, the at least one processormay operate to cause the drives to move the panel that the user haspreviously manually moved to the first position, back to the secondposition. In alternative embodiments the at least one processor mayoperate to cause the panels to be moved to the first position at adetermined point in a transaction, but may rely on a user to manuallymove the panels from the first position back to the second position.Further yet in some other alternative embodiments, the drives may beoperative to move the panels but the transmission mechanism may be suchthat the user can override the drives and move the panels to positionsas the user may desire at certain times or at any time during atransaction. Of course these approaches are exemplary and in otherembodiments other approaches may be used.

It should be understood that embodiments described with movable panelsmay incorporate features like those previously described in connectionwith other embodiments. This may include for example provisions toprovide lighting to facilitate user operation of the machine. Suchlighting may be incorporated in the panels or in other locations of thefascia so as to facilitate user operation. Alternatively or in additionin other embodiments lighting may be provided through the panels or inother locations so as to provide outputs which are effective to obscurethe viewing of user inputs. This may be done for example by providingfiberoptic output points or other lighting from the outputs of thepanels.

It should be understood that in other embodiments the panels and fasciamay have other configurations. This may include for example, panels thatrotate to lie flush relative to a fascia surface when not in use.Alternatively, panels may be retractable relative to the fascia. Forexample, the panels may move generally vertically to raise and lowerthem relative to the key pad at appropriate times. In still otherembodiments panel structures may be made to expand and retract atappropriate times. Of course, other approaches and structures may beused.

In still other embodiments provision may be made for changing propertiesof the panels or the covers. This may include for example providing fora liquid crystal material to be encapsulated within the panels or othertypes of covers previously discussed. Such a liquid crystal material maybe acted upon by electrical fields so as to selectively change thematerial in various selected regions from transparent to opaque. Thisenables the machine for example, to enable a portion of a panel or acover to be made transparent upon the sensing of the user's digit in anarea adjacent to the keypad. Alternatively or in addition provision canbe made for sensing the position of particular digits within a cover oradjacent to a panel using sensors such as infrared, optical, ultrasonicor other suitable sensors. One or more processors in the ATM may operatepursuant to the sensed location of the user's digit to render the liquidcrystal material transparent only in the vicinity of the particulardigit while keeping the remainder of the cover or panel opaque so as tominimize the risk of unauthorized viewing. Other embodiments mayincorporate polarizing features or Fresnel lens effects to achievevisibility from the point of view of the user while reducing the risk ofunauthorized observation. Of course as previously discussed Fresnel lenseffects achieved through liquid crystal may also provide other desirableproperties including magnification or obfuscation. In additionresponsive to operation of at least one processor in the machine theeffects achieved may be varied responsive to operation of the machine.This may provide for example limiting observation capabilities to thepoint of view of the machine user during input of a user's PIN whileenabling greater visibility of other portions of the cover during othertransaction steps. Of course these approaches are exemplary.

Alternatively or in addition provision may be made for assuring thevisibility through such covers or panels using the principles previouslydiscussed for detecting or eliminating the buildup of dirt orcondensation. Further in alternative embodiments provision may be madeto minimize the effect of undesirable bacterial accumulation on the keysof the keypad. This may include for example providing for the dispersalof disinfectant material of a generally transparent nature onto thekeypad and within the interior and exterior surfaces of a keypad coverand panels. Aerosol materials including disinfectants may likewise beprovided in suitable locations adjacent to the keypad. This may beaccomplished for example through the programming of one or moreprocessors in the machine which enable a dispersal of an aerosoldisinfectant onto the keypad and adjacent structures on a programmedbasis. In some embodiments the machine may include a supply ofdisinfectant material. Suitable pumps and aeration devices may beprovided for delivering the disinfectant into and/or on the surfaceswhere bacterial growth is to be inhibited. Such dispersal of materialmay be accomplished responsive to operation of at least one processor ofthe machine to correspond to particular conditions. This may include forexample at times when the machine is not operating to conducttransactions. The at least one processor may also operate in accordancewith its programming to provide the antibacterial material whenenvironmental conditions are suitable such as temperature and humidityare within particular ranges. In still other embodiments the machine mayinclude a device for generating ozone. Such generation may be doneresponsive to operation of the processor and the ozone materialdelivered at appropriate times and in appropriate areas for purposes ofdisinfecting areas of the machine. Of course these approaches areexemplary.

Alternatively or in addition air flow provided from the machine in thearea adjacent to a cover or panels so as to reduce the risk ofcondensation may also include the dispersal of an aerosol disinfectantinto the area adjacent to the keypad. Of course it should be understoodthat a supply of such disinfectant may be provided in the machine andmay be included for example so as to provide suitable disinfecting atpoints where users would generally be expected to come in contact withthe machine in addition to the keypad. This may include for example thearea adjacent to card readers, function keys, touchscreens or otherlocations which provide user contact. Of course these approaches areexemplary and in other embodiments other approaches maybe used

In some embodiments the ATM may include a supply of disinfectant lotionthat is suitable for application to a user's hands. The ATM may includea suitable pump and outlet in connection with the supply that providesfor output of the disinfectant lotion from the machine in a way thatenables the user to rub the lotion on their hands. For example, the atleast one processor in the ATM may be programmed to offer a user anoption through an output device of the ATM to select to have thedisinfectant dispensed from an outlet so they can apply it to theirhands. This may be done, for example, when a user indicates they areending their transaction session at the ATM, which may involve thereturn of their card from the machine. In response to the userindicating through an input to an input device that they wish to havesuch lotion, the processor in the ATM will cause the pump to operate todispense an amount of lotion to the user. The user can then apply thelotion to their hands immediately after use of the ATM.

Alternatively, some embodiments may offer the user an option to receivedisinfectant lotion near the start of a transaction session. This mayinclude for example, in response to a user input. This may be forexample, a manual input. Alternatively lotion may be dispensed inresponse to a sensor on the machine sensing a user's efforts todisinfect the machine, such as with a portable ultraviolet (UV) light aslater described. Alternatively the ATM may be programmed to dispensedisinfectant lotion to the user unless the user provides an inputindicating they do not wish to receive the disinfectant lotion. Ofcourse these approaches are exemplary.

In still other alternative embodiments disinfectant may be dispensed ina packaged form. This may include, for example, dispensing a containerholding the disinfectant for a user's skin from the machine. In someembodiments, the disinfectant may be an antibacterial liquid or gelmaterial included in a generally flat containers, similar to foil orplastic packages used for holding food items such as small quantities ofketchup or mustard, which can be dispensed from the machine. In stillother embodiments the disinfectant may be on cloth or other substrate,and dispensed in a packet comprised of foil, plastic or other fluidtight material. Alternatively, such packages may be attached to sheetmaterials which may be dispensed form the machine in a manner similar tobills, envelopes or other sheet materials. The container may bereleasably adhered to, or made an integral part of the sheet material.This may enable the material to be stored in containers and dispensedfrom the machine in a manner comparable to notes and other sheets.Alternatively, such disinfectant material may be placed in or on sheetsor envelopes and dispensed in a manner like that shown for envelopes inU.S. Pat. No. 7,103,958, the disclosure of which is incorporated byreference. The approach of the incorporated disclosure may also be usedto dispense to a user the disinfectant material in an envelope or othercontainer. The waste material after use can then be placed in thecontainer and discarded in a suitable waste container when the user isdone. In some embodiments the machine itself may accept the wastematerial therein for disposal. In some embodiments a machine user mayreceive such disinfectant from the machine either at the beginning orend of a transaction session. Further the machine may be operative tocharge some or all users for such disinfectant material. This may beaccomplished through the programming associated with at least oneprocessor of the machine.

In exemplary embodiments, to produce a suitable disinfectant, generallyflat fluid tight packets may be attached to sheets or envelopes ofmaterial which are sized to be dispensed by a sheet dispenser (orenvelope dispenser) in the machine. Such attachment may be through asuitable means that maintains engagement, such as by adhesive (forexample), staples or in the case of an envelope or other container,placing the package inside the envelope or container. The sheet (orenvelope which for purposes hereof will be considered sheet material) isthen placed in the machine for dispensing from the machine. The sheetmaterials with the disinfectant may be placed in a sheet holdingcassette of a type used to house currency notes form the machine. Thecassette may then be placed in the machine and the sheets withdisinfectant packages attached selectively dispensed to users.Alternatively the sheet materials may be placed in another location inthe machine from which they may be selectively dispensed.

Alternatively sheet materials may be formed to include integraldisinfectant holding packages. For example, sheet structures sized to bedispensed from the machine may be formed to include pockets therein inwhich disinfectant materials (or cloth or other substrates bearingdisinfectant materials) are housed. Such pockets may be bounded bymaterials which are generally fluid tight and hold the disinfectantsecurely until a user deliberately breaks the pocket to access thedisinfectant. For example, sheets with pockets may be formed by adheringsheet materials in a blister pack or other sandwich structure. Of coursethese approaches are exemplary.

Ultraviolet (UV) radiation may be used in some embodiments to provide adisinfecting function for manual contact points on an ATM. FIG. 48 showsan ATM fascia 540 which includes a number of manual contact points onthe machine which may come into contact with the fingers of usersoperating the machine. These contact points include function keys 542. Aplurality of function keys 542 are positioned on each side of a display544. In this exemplary embodiment the function keys 542 are positionedbetween the display and a corresponding side surface 546 that extendsoutwardly from the fascia beyond the surface of the display in thefascia keys.

The exemplary ATM in FIG. 48 also includes a keypad 548. Keypad 548includes a plurality of manually actuatable keys of the type previouslydescribed. Keypad 548 has in overlying relation thereof a keypad shieldor cover 550. Each of the keys of the keypad as well as the area withinthe keypad cover may be commonly contacted by user fingers in operationof the machine.

Also included in the exemplary user interface shown is a headphone jack552. Headphone jack 552 is adapted to receive plug in connectors fromheadphones used by visually impaired persons in the operation of themachine. An area adjacent to the headphone jack 552 will commonly becontacted by fingers of machine users particularly visually impairedusers.

The exemplary ATM also includes a card reader of the type previouslydiscussed which is in operative connection with a card reader opening556. The card reader opening is operative to pass magnetic stripe cardsor other card types therethrough. In the exemplary embodiment the cardreader opening is surrounded by a card housing 558. In the exemplaryembodiment the card housing is of the type that includes selectivelyilluminatable light indicators therein so as to facilitate the abilityof users to insert and receive cards through the card reader opening. Instill further embodiments the card housing may be of the type thatincludes features that are usable to detect the installation of anunauthorized card reading device adjacent to the card reader. Forexample the housing may be of the type described in U.S. patentapplication Ser. No. 10/722,067 filed Nov. 25, 2003, the disclosure ofwhich is incorporated herein by reference. The area adjacent to the cardreader opening which includes the card housing constitutes an area inwhich machine users to generally contact the machine with their fingersduring the course of operation thereof.

The exemplary ATM shown in FIG. 48 also includes a receipt printer. Areceipt printer is in operative connection with a paper outlet 560. Thepaper outlet area generally indicated 562, extends generally adjacent tothe paper outlet in an area where users will commonly contact themachine fascia when taking receipts that are printed by the machineduring transactions. A cash dispenser outlet 564 is operative to delivercash from the ATM to users. In this exemplary embodiment the cashdispenser outlet is generally blocked by one or more gate members 566except when the ATM is operating to deliver cash to a user. During suchtimes at least one processor of the machine is operative to cause anactuator to move the gate member so that currency bills can be extendedtherethrough. A cash outlet area generally indicated 568 includes anarea that extends generally adjacent to the cash dispenser outlet (andmay include the outlet as 5 well as the gate member thereof) and whichusers generally contact the machine with their fingers when obtainingcash from the machine.

In this exemplary embodiment the ATM further includes at least onecustomer sensor schematically indicated 570. Customer sensor 570 isoperative to sense users in proximity to the ATM. In some embodimentsthe customer sensor 570 may include an optical sensor, a sonic sensor,an ultrasonic sensor, inductance sensor or other type sensor suitablefor detecting the presence of a person. It should be understood thatalthough the sensor shown is positioned on the fascia, other positionsand types of sensors may be used. These may include for example, camerasin connection with devices which conduct analysis of image data thatidentify images that include a person adjacent the machine. Other typesof customer sensors such as weight sensors, heat sensors or other typesof sensors may be used. In the exemplary embodiment the customer sensoris in operative connection with the at least one processor of themachine so as to carry out steps such as those that are hereinafterdescribed.

In this exemplary embodiment a plurality of UV light sources arepositioned so as to emit UV light onto surfaces of the ATM that arecommonly contacted by users' fingers in the course of conductingtransactions. In some exemplary embodiments a plurality of UV lightsources that output ultraviolet light in one or more of the UV-A, UV-Band/or UV-C bands may operate to cause ultraviolet light to be emittedin a manner that contacts surfaces of the ATM. Such UV light contact maybe of sufficient length and intensity to kill germs and provide adisinfecting function on the surfaces of the ATM that are routinelycontacted by user fingers.

In the embodiment represented in FIG. 49, a UV light source 572 shown inphantom, is positioned in supporting relation of the side surface 546 onthe right side of the fascia as shown. The UV light source 572 isoperative to cause UV light to contact the area of the fascia indicatedby the circular area 574. Area 574 includes function keys 542 on theright side of the fascia. A further UV light source 576 shown in phantomis in supporting connection with the opposed side surface 546. UV lightsource 576 emits UV light that contacts an area schematically indicated578 which includes the function keys 542 on the left side of the fascia.

In this exemplary embodiment the ATM further includes a UV light source580 in supporting connection with the keypad cover 550. UV light source580 is selectively operative to output UV light and is operative tocause the UV light to contact an area 582 that includes the keys of thekeypad.

It should be understood that in still other embodiments UV light sourcesmay be positioned so as to cause UV light to contact the card area inthe area of the card housing 558, the paper outlet area 562 and/or thecash outlet area 568. Of course in other embodiments other or differentareas may be contacted by UV light so as to achieve disinfecting ofother customer contact points.

In the exemplary embodiment each of the UV light sources is in operativeconnection through appropriate circuitry with at least one processor inthe machine. The at least one processor operates in accordance with itsassociated programming to selectively cause the UV light sources tooperate and output such UV light in a manner that will facilitatedisinfecting the areas of the machine that are contacted by the UVlight.

In some exemplary embodiments UV light sources may also be included inthe interior of the ATM housing. This may include for example UV lightsources that are operative to contact currency bills that are beingaccepted into and/or dispensed from the machine. In such embodiments oneor more UV light sources may be operative to cause UV light to contactcurrency bills moving through one or more transports in the machine.This will help to assure that currency bills received from users receivethe benefit of disinfecting UV light contact prior to be stored in themachine. Likewise UV light sources in the machine may cause the UV lightto contact passing bills that are moving toward a machine outlet so asto be dispensed from the machine. This will help to assure that billsreceived by customers are treated prior to receipt thereby.

Alternatively or in addition UV light sources within the machine may beoperated to disinfect an area inside a card reader in which cardsreceived from users pass during operation of the machine. This mayinclude for example a card transport area through which user cards aremoved to read such cards and hold them during operation of the machine.Such a card transport area as well as devices therein are shown in U.S.Pat. No. 7,032,245 the disclosure of which is incorporated herein byreference. In some exemplary embodiments the UV light source may beoperative to cause UV light to contact structures within the cardtransport area of a card reader during times that user cards are notpositioned therein. Alternatively or in addition, UV light sources maybe operated to cause UV light to contact user cards positioned withinthe transport.

In still other embodiments UV light may be used to disinfect other typesof items that are received by or dispensed from the machine. Further insome embodiments other disinfectant techniques of the types previouslydescribed or other approaches may be used in combination with UV lightto disinfect items internally or externally of the machine as well as todisinfect points of manual contact with the machine.

In some exemplary embodiments the UV light sources are in operativeconnection with the at least one processor to facilitate operating theUV light sources at appropriate times. This includes for example,operating the UV light sources within the machine at times when itemsare being moved to be dispensed from the machine such as currency bills.The at least one processor may be operative to cause the UV lightsources within the machine to disinfect the currency bills as they aremoving toward the cash outlet opening in the machine. Likewise the atleast one processor may be operative in accordance with its programmingto cause a UV light source positioned adjacent to a card reader and acard transport area therein, to cause UV light to contact a user's cardin the card transport path as it is moved or otherwise positionedtherein. Likewise the at least one processor may operate at appropriatetimes to cause UV light to operate and disinfect items received by ordispensed from the machine.

The at least one processor may also be in operative connection with theUV light sources that operate to cause UV light to contact manualcontact areas of the ATM so as to disinfect those areas of the machine.This may be done in some exemplary embodiments after each transactionsession carried out by the machine. In this exemplary embodiment atransaction session includes one or more transaction activities carriedout by a given user at the machine between when the user's card is inputto a card reader of the machine and a time when the card is taken fromthe machine. For example the at least one processor may operate inaccordance with its programming to determine that the user has completedthe transaction session and has taken their card. The processor thenoperates to cause each of the UV light sources to output UV light thatcontacts the respective associated manual contact points of the machine.This may be done for a time period as is appropriate to disinfect theareas contacted, which is generally a short period of time. During thisperiod the at least one processor may operate to cause the display ofthe ATM to output at least one message instructing any users who maybewaiting at the machine to wait while the machine operates to conduct thedisinfecting activities. Of course it should be understood that in someembodiments the display may not output a message specifically indicatingthe particular disinfecting activity that is occurring. Once theactivity is complete the at least one processor may operate to provideindicia which includes instructions for the waiting user to begin theirtransaction session. Of course this approach is exemplary.

In still other embodiments the at least one processor may operate inaccordance with its programming to determine the nature of thetransaction conducted by the user who has completed the immediatelypreceding transaction session. The at least one processor may beprogrammed to have the capability to determine exactly what manualcontact points the user contacted in the course of performing theirtransaction. For example the user may have only contacted function keyson the one side of the display rather than both sides. Likewise the usermay have conducted transactions that would not have resulted in the userreceiving a receipt, and thus the user would not have contacted thepaper outlet area 562 of the machine. In such embodiments the at leastone processor may operate in accordance with its programming to onlycause the UV light sources corresponding to the particular areas thatwould have been manually 20 contacted by the user to output UV lightthat contacts the corresponding machine contact areas. Such an approachmay serve to reduce the number of cycles in which UV light is output andalso reduce the exposure of the particular areas of the machine to theUV light which may have a tendency to degrade certain materials overtime.

In still other embodiments the at least one processor can operateresponsive to sensing a customer with the customer sensor 570 to causethe UV light sources to operate prior to the user commencing atransaction. For example upon sensing a customer approaching the machinethe at least one processor may cause the display to output at least onemessage advising the user to wait for a brief period while the machineis disinfected. During at least a portion of the time that this messageis output the at least one processor may be operative to cause the UVlight sources 30 to disinfect the areas of the machine with UV light.After the disinfection activity has occurred the at least one processormay then be operative to output through the display at least one messageadvising the user to insert their card or otherwise initiate atransaction session. Alternatively or in addition embodiments may alsooperate to disinfect user contact areas both before and aftertransaction sessions. The user may also be offered disinfectant lotionor the dispense of a disinfectant material. Of course these approachesare exemplary.

In still other embodiments other approaches may be used to facilitatedisinfecting user contact surfaces of ATMs. FIG. 50 shows a handheld UVemitting unit 584. The exemplary handheld unit 584 is designed to be arelatively small size and suitable for a user to carry around in apocket, on a key ring or in another manner similar to a small portableflashlight or similar device. The handheld unit 584 includes inputdevices 586 that are used by a person to control operation of thehandheld unit. The input devices 586 are operative to selectively causethe unit to output disinfecting UV light as schematically represented bythe area 588.

In an exemplary embodiment an ATM user may use the handheld unit 584 toselectively disinfect manual contact areas on an ATM before commencing atransaction session. For example as represented in FIG. 51 the user maydirect a handheld unit to output UV light that contacts surfaces of thekeypad cover and keypad. This may be done to enable the user todisinfect the areas that they wish to contact on the machine beforecommencing a transaction session or during a transaction session.Likewise the user may operate the handheld device to selectivelydisinfect other manual contact areas on the machine.

Further in some exemplary embodiments the ATM fascia may include one ormore sensors schematically indicated 590. In the exemplary embodimentthe sensors 590 are operative to sense UV light of the type that wouldbe output by a handheld unit of the type described. Such sensors 590 arein operative connection with appropriate circuitry including the atleast one processor. This enables the at least one processor todetermine that a person is disinfecting areas of the ATM. In someembodiments the at least one processor of the machine may operate inaccordance with its programming to perform various functions in responseto sensing the disinfecting action by the ATM user. Such actions mayinclude for example causing the processor not to actuate the UV lightsources on the machine in response to sensing that the user isdisinfecting the machine directly. This will avoid unnecessary operationof the UV light sources and help to prolong their useful life.Alternatively or in addition the at least one processor may operate tocause at least one output through a display that indicates to the userthat the machine has sensed that they are disinfecting the machine andto instruct the user to insert their card when they are ready toproceed. Alternatively the ATM may operate to offer the user a dispenseof disinfectant.

Alternatively in some embodiments the at least one processor may operatein response to sensing the disinfecting activity by the user to causethe UV light sources on the machine to also operate. The at least oneprocessor may cause an output through the display in such circumstancesto indicate to the user that they need not disinfect the contact areasof the machine with their handheld unit as the machine is doing soautomatically. Such instructions would save the user the time andinconvenience of disinfecting the contact points themselves. It wouldalso give the user greater confidence that the machine is adequatelyperforming disinfecting activities. Of course these approaches areexemplary and in other embodiments other approaches that may be used.

FIGS. 43 through 44 disclose yet a further embodiment of the device forreducing the risk of unauthorized interception of user inputs providedthrough a keypad of an ATM. A further ATM fascia 470 includes a keypad472 including a plurality of keys that are actuatable by a user'sdigits. A cover 474 is used to minimize the risk of unauthorizedinterception of inputs through the keypad. Exemplary cover 474 includesa pair of tapered side wall portions 476. Side wall portions 476terminate in inturned flange portions 478. Inturned flange portions 478are attached to the fascia. Such attachment may be made in a manner likethat previously discussed. Cover 474 includes a top portion 480. The topportion 480 is tapered in a manner generally similar to that discussedin connection with cover 430. The top portion 480 and side wall portions476 bound an opening 482. Opening 482 overlies at least portions of someof the keys of the keypad in the exemplary embodiment. The opening 482also enables an ATM user to view engagement of their digits with all ofthe keys of the keypad.

As best shown in FIG. 43 the cover 474 includes a flap portion 484. Inthe exemplary embodiment, flap portion 484 is bounded on each transverseside by a slot 486. In the exemplary embodiment the cover 474 iscomprised of a flexible material such as a molded urethane. The flexiblematerial of this exemplary embodiment is sufficiently rigid to generallymaintain its shape when a user's hand and/or digits are not presentwithin the cover. However, in the exemplary embodiment the flexiblenature of the cover 474 enables a user to deform the cover throughengagement with their hand and/or fingers when providing inputs to themachine. For example in the exemplary embodiment the flap portion 484 isenabled to be deformed by the back of the ATM user's hand or fingers ina direction that is generally upward 5 and outward. The slots 46facilitate the ability of the flap portion to move as desired by a user.

The deformation of the flap portion may in some embodiments enable auser to more readily view keys of the keypad that are positioned beneaththe flap portion in the undeformed condition of the cover. Likewise auser's hand can deform the side wall portions of the cover to facilitateaccess and observation to selected keys. This approach can facilitateoperation of the 10 ATM by the user. Further in exemplary embodimentsthe deformability and resilient character of the cover may preventdamage and breakage to which covers of more rigid material may besusceptible. Of course it should be understood that although in theembodiment described the entire cover is comprised of flexible material,in other embodiments only selected portions may be comprised of suchmaterial while other portions may be comprised of more rigid materials.Further, this exemplary embodiment may be combined with features ofother covers and security devices that are described herein.

In still other embodiments a cover may be provided that is selectivelymovable responsive to at least one processor in the machine betweendifferent shapes. For example in an exemplary embodiment a coveroverlying the keypad may be selectively changed between an 20 operativeposition in which a user can access with their digits all of the keys ofthe keypad, and a collapsed position in which at least some of the keysof the keypad cannot be accessed by a user. This may be accomplished inexemplary embodiments responsive to one or more processors of themachine that operate to place the cover in an operative position whenthe machine is in a state in which it is able to accept keypad inputsfrom the user. Similarly in some embodiments the at least one processormay cause the cover to be in the collapsed position when the machine isnot in an operative position to accept keypad inputs from the user. Inthe collapsed position the cover may operate to help to protect thekeypad from vandalism, the elements or other undesirable conditions. Ofcourse this approach is exemplary.

FIG. 45 shows an alternative keypad cover 488. Cover 488 is comprised ofsuitable 30 flexible material that enables the deformation thereof.Cover 488 includes a plurality of members 490 in supporting connectiontherewith. In the exemplary embodiment the members 490 may be comprisedof shape memory alloy material of a type that changes between differentshaped configurations based on the application of electrical energythereto.

In the exemplary embodiment of cover 488, the members are in operativeelectrical connection with a driver 492 which is operative to providesuitable electrical energy to cause the members 490 to change from afirst shape to a second shape. The at least one driver 492 is inoperative connection with at least one processor 494 of the automatedbanking machine. Processor 494 may in some embodiments include theprocessors and the controllers that operate to cause the machine tocarry out the transaction functions. In other embodiments the at leastone processor 494 may include one or more processors that are other thanthose that primarily cause the machine to carry out transactions, but isin operative connection therewith.

In the exemplary embodiment when the ATM is carrying out transactionfunctions in response to at least one processor, the cover 488 may be ina collapsed position as shown in FIG. 44. In the collapsed position theside walls and top portion of the cover are disposed in close overlyingrelation of several keys of the keypad. The inner face of the side wallsand top portion are also disposed in close adjacent relation of the keysso as to generally prevent digit access to at least some of the keys ofthe keypad. Of course in some embodiments even with the cover in thecollapsed position at least some keys of the keypad may be digitaccessible. This is represented by keys 496. Of course this approach isexemplary.

When the ATM operates to conduct transactions and/or the transactionflow reaches a state in which the machine is ready to accept acustomer's personal identification number (PIN), numerical values orother inputs through the keypad, the at least one processor 494 isoperative to cause the driver 492 to actuate the members 490. Uponactuation of the members the flexible material of the cover 488 deformsand changes shape such that the cover of the exemplary embodimentgenerally corresponds to the shape of cover 474. In this operativeposition the user of the ATM is enabled to access with at least onedigit all of the keys of the keypad and to view digit engagement witheach of the keys from the point of view of the user.

In an exemplary embodiment the at least one processor of the machine isoperative to cause the cover 488 to remain in the operative positionthroughout the user transaction session. For example the cover mayremain in the operative configuration while the user inputs their PIN,numerical values and other inputs until the user indicates to themachine that they do not wish to conduct any further transactions.Thereafter the at least one processor 494 operates to cause the at leastone driver to change the shape of the member 490 and in response whenthe cover 488 returns to the collapsed position. Of course this approachis exemplary.

It should be understood that covers which are changeable between anoperative position and a collapsed position may operate using othertypes of structures to achieve changes in shape. FIG. 46 shows anexemplary embodiment of a cover 498. Cover 498 includes a plurality offluid cavities 500 therein. In the exemplary embodiment the fluidcavities are embedded in the flexible cover and are fluidly connected toone another as well as to a port schematically indicated 502. In thisexemplary embodiment the port 502 is operative to selectively apply andrelease fluid pressure to the fluid cavities in the cover. Of course itshould be understood that this approach is exemplary.

In this embodiment the port 502 is operative to have fluid pressureapplied thereto and relieved therefrom responsive to a three-way valveschematically indicated 504. Valve 504 is in fluid communication with afluid source 506 such as a small air compressor included in the ATM. Ofcourse in other embodiments other sources of compressible orincompressible fluid may be used. In the exemplary embodiment the fluidsource 506 and the valve 504 are in operative connection with at leastone processor 508. Processor 508 may in some embodiments comprise theprocessor which executes instructions in the ATM to cause the ATM tocarry out transactions, or may be a separate processor in operativeconnection therewith.

In this exemplary embodiment the cover 498 is operative to changebetween an operative position in which an ATM user is enabled to accesswith at least one digit all of the keys of the underlying keypad, and acollapsed condition in which digit access to at least some of the keysof the keypad are prevented. This is accomplished in the exemplaryembodiment through operation of the at least one processor 508 causingthe fluid source 506 and the valve 504 to apply fluid pressure to port502. In this exemplary embodiment the fluid pressure is transmitted tothe fluid cavities 500 which causes the cover 498 to change shape to theoperative position. In the operative position an ATM user is operativeto provide inputs through the keypad Thereafter responsive to operationof the ATM and the state thereof in which an ATM user no longer needs toprovide inputs through the keypad, the at least one processor 508changes the condition of the valve 504 to relieve fluid pressure fromthe port 502 and the fluid cavities 500. This causes the exemplary cover498 to change to the collapsed condition. Of course it should beunderstood that elastic materials or other biasing mechanisms as well asthe drawing of vacuum on the fluid cavities may be provided in someembodiments to facilitate the contraction 5 of the cover into acollapsed position.

It should be understood however that the use of shaped memory membersand fluid pressure to change the configuration of the cover and othersecurity devices associated with input devices of an ATM, are merelyexemplary and in other embodiments other approaches maybe used.

FIG. 47 shows yet a further embodiment which may be used in an ATM. Thisembodiment may be used in conjunction with features of other embodimentsdescribed or incorporated by reference. FIG. 47 shows a keypad 510.Keypad 510 of this embodiment comprises a plurality of keys 512 throughwhich an ATM user can provide inputs by accessing the keys with manualdigits. Keypad 510 may be of a configuration like that described inother embodiments herein.

The keypad 510 of an exemplary embodiment comprises an encrypting PINpad (EPP) which is selectively operative to receive inputs through thekeys, and encrypt corresponding key input signals within the keypad sothat the output from the keypad is encrypted. This approach may be usedin some embodiments to reduce the risk that a criminal could decipherATM user inputs such as a user's PIN. The keypad 510 of the exemplaryembodiment is also selectively operative to provide unencrypted outputsresponsive to user inputs through the keys. This is done in the courseof transactions where the inputs of a user are not necessarilyconfidential, such as inputs corresponding to amount data related totransactions a user is conducting, transaction selections or otherinputs of a type that would not allow a criminal to compromise securityfor a user's account or other personal data.

In the exemplary embodiment the keypad 510 includes at least oneinternal processor 514. The processor 514 is in operative connectionwith the at least one data store 516. In an exemplary embodiment thedata store may include digital certificates, at least one public key andat least one private key. The at least one data store 516 may alsoinclude other programmed instructions that facilitate maintaining thesecurity of the keypad as well as the ATM. Exemplary embodiments of thekeypad may include features of those described in U.S. patentapplication Ser. No. 10/126,808 filed Apr. 19, 2002, the disclosure ofwhich is incorporated herein by reference. Of course this approach isexemplary.

In this exemplary embodiment the keypad 510 is in operative connectionwith at least one processor 518 of the ATM. Processor 518 of theexemplary embodiment is in operative connection with at least one datastore. Processor 518 is also in operative connection with a plurality oftransaction function devices schematically indicated 522. Thetransaction function devices may include devices that operate in the ATMresponsive to the at least one processor 518. These devices may includefor example some or all of a display, a card reader, cash dispenser,depository, check acceptor and other devices operative in the machine tocarry out transactions.

In this exemplary embodiment the at least one processor 518 executesprogrammed instructions stored in at least one data store and which areoperative to cause the machine to carry out transactions. Asschematically indicated, the at least one processor 518 is operative tocommunicate through at least one appropriate interface in a network 524.Network 524 enables the ATM to communicate with at least one remotecomputer schematically indicated 526. The at least one remote computerwith which the ATM communicates may include for example, a financialtransaction computer which transfers funds and keeps track of accountsheld by users of the machine. Of course it should be appreciated that invarious embodiments the ATM may communicate through numerous differentnetworks and with numerous different remote computers. The configurationshown in FIG. 47 is merely schematic.

In exemplary embodiments the at least one processor 518 is in operativeconnection with a visual indicator 528. Visual indicator 528 of anexemplary embodiment comprises a light emitter which is changeablebetween illuminated and un-illuminated conditions. The visual indicator528 is included in the user interface of the machine. In someembodiments it may be operatively connected to the processor through thekeypad as shown, or may be connected in other ways. In addition in someexemplary embodiments other types of visual indicators may be used.These may include for example changeable signage indicators, outputsthrough the display of the user interface, mechanical indicators orother suitable indicators to indicate to a user that inputs they provideat certain times during transactions are being encrypted.

In the exemplary embodiment the at least one processor 518 is operativeto cause the ATM to carry out transactions. In an exemplary transactionflow the machine may output one or more instructions through the displayto indicate to the user that the machine is ready to receive aconfidential input such as a user's PIN. Responsive to the at least oneprocessor being in this condition the processor sends at least onesignal to the keypad 510 which causes the keypad to encrypt the inputsthereto prior to delivering signals corresponding to such inputs to theat least one processor. In the exemplary embodiment the at least oneprocessor is operative responsive to providing the output which causesthe keypad to encrypt inputs, to also cause the at least one visualindicator 528 to provide a visual output. This visual output indicatesto the user that the inputs that they are now providing through thekeypad are encrypted.

In the exemplary embodiment the at least one processor providesinstructions through a display or other output device to the user whichinstructs the user to input their PIN, and when they are done to providean end input. This may include for example pressing a particular key ofthe keypad or other key or input device of the machine. In the exemplaryembodiment responsive to receipt of this end input the at least oneprocessor is operative to send at least one signal that causes thekeypad 510 to cease its encrypting functions. Further the signals fromthe at least one processor are also operative to cause the at least onevisual indicator 528 to change its condition as well. This indicates tothe ATM user that inputs through the keypad are no longer beingencrypted. Of course this approach is exemplary.

In further transaction steps the at least one processor 518 may provideinstructions to a user through a screen or other output device. Theseinstructions may include instructions for a user to input selectednumerical values or other items through the keypad. In such conditionsthe at least one processor is operative through signals to the keypad tocause the keypad to receive such inputs and deliver signalscorresponding to the inputs to the at least one processor in anunencrypted manner. During receipt of such signals which are not securedthrough encryption, the at least one processor is operative to cause theat least one visual indicator to be in a condition in which it indicatesthat the inputs are not encrypted. This may be to have the lightemitting device off. Of course this approach is exemplary.

The function of providing to an ATM user an indication that sensitiveinputs such as the PIN are being encrypted may help to increase userconfidence that their personal data is being secured. In addition thefailure of the at least one visual indicator to operate at times when auser is being requested to input a PIN or other confidential data, mayprovide an indication to a user that the ATM has been potentiallysubject to tampering and should not be used.

In some embodiments the at least one visual indicator may be included onthe keypad. In some exemplary embodiments the indicator may include anilluminated indicator such as a lock, which is indicated 530 in FIG. 47.The exemplary indicator including a lock graphic may serve tocommunicate to the ATM user that their inputs to the keypad are secure.In some exemplary embodiments the indicator may be made as an integralpart of a tamper resistant input device such as an Encrypting PIN Pad(EPP). The EPP may be made so that any tampering therewith orunauthorized programming thereof will cause the encryption indicator tocease to function or to function in ways associated with an undesirablecondition. In this way it is less likely that a corrupted device will beinstalled on a banking machine and used by unwary users. In still otherembodiments, the at least one processor may cause an output indicatingan encrypting condition of a device through the display or other outputdevice of the banking machine. This may include a visual output throughthe screen which includes a word output such as “keypad input now beingencrypted” and/or the output of icons, graphics or other indicatingoutputs. Of course these approaches are exemplary.

Principles like that applied in connection with the exemplary keypad 510may also be applied through other transaction devices of ATMs that areoperative to receive sensitive user inputs. For example a card readerschematically indicated 542 may include capabilities for selectivelyproviding encrypted outputs corresponding to the data read from thecards of ATM users. Exemplary embodiments may also include visualindicators 534 which are operative to indicate to ATM users that adevice is operating to encrypt the inputs that are being receivedtherethrough. Such indicators may be in addition to or in lieu ofindicators of the type previously discussed which are operative toindicate the condition of the device and/or to draw a user's attentionthereto. Of course it should be understood that these approaches areexemplary.

In still other exemplary embodiments provision may be made for reducingthe risk of unauthorized access to customers' confidential informationsuch as a PIN number. These additional features may include for example,guarding against situations where criminals have programmed the ATM orotherwise operatively connected to it in a way that causes the ATM torequest that a user input their confidential information at a time whenthe keypad or other device is not operating to encrypt inputs. This maybe done for example by including unauthorized computer executableinstructions in a data store associated with at least one processor ofthe ATM. Alternatively or in addition, this might be accomplished byprogramming the ATM in a way that causes the ATM to connect to a networkaddress which causes the ATM to output a request for the user to inputtheir confidential information. In still other situations criminals mayinclude additional processors or other devices in the ATM that sendsignals to the display to provide outputs through the display, whichrequest a user to input their confidential information to the ATM.

As can be appreciated these unauthorized outputs through the display orother output device can cause the user to input their confidentialinformation at times during operation of the ATM when the authorizedprogramming is not causing the user inputs to be encrypted. As a resultcriminals can gather the unencrypted data corresponding to confidentialinputs and later use the information to obtain unauthorized access tothe user's account. In some situations this may be done by storing datacorresponding to these inputs in at least one data store in the ATMwhich can later be recovered either locally or remotely. Alternativelyor in addition, in some situations the criminals may provide for theinputs to be delivered from the machine through a network to a remotelocation so as to minimize the risk of detection. Of course theseapproaches are exemplary of criminal exploits that may be attempted atautomated banking machines.

As can be appreciated, in the exemplary embodiment of the ATM duringnormal operation of the at least one processor 518, the at least onedata store 520 includes computer executable instructions which cause theat least one processor to operate the ATM to carry out transactions.These computer executable instructions cause the computer to carry outat least one transaction sequence. The transaction sequence that iscarried out includes a plurality of states in which the machine isenabled to carry out certain transaction functions. For example in anexemplary embodiment, the at least one processor may wait for a customerto begin a transaction and may output certain displays to attract acustomer to the machine. This step in the transaction sequence isassociated with a wait state in which the machine is waiting for aninitial input from a user to commence a transaction. In an exemplaryembodiment the machine senses that the user has presented a card to anopening associated with a card reader, or that a user has otherwiseengaged a similar article with the machine. In response to sensing theseinputs the computer executable instructions of the at least oneprocessor causes the machine to be in a card read state associated withthe transaction sequence in which the card or other article has dataread therefrom.

Thereafter responsive to being able to read the card, the at least oneprocessor may then operate in accordance with the computer executableinstructions to cause the at least one processor to be placed in a PINentry state of the transaction sequence. In the PIN entry state of theexemplary embodiment, the at least one processor operates in conjunctionwith the encrypting PIN pad, namely keypad 510. The keypad operates inaccordance with its programming and the instructions from the at leastone processor to encrypt inputs from a user that are provided throughthe keypad. Input of an indication that the PIN has been provided, thencauses the at least one processor to move to a next state in thetransaction sequence in which the user is presented with options throughthe display for selecting a type of transaction that they wish toconduct at the machine.

The at least one processor of the machine in its normal operation stepsthrough a series of states which have associated functions, operationsand outputs that enable the ATM to carry out different transactions. Ascan be appreciated in the exemplary transaction flow provisions are madein various states for the transaction to take different paths from agiven state in the transaction sequence. For example in the transactionselection state the user may be asked if they wish to receive cash or ifthey wish to make a deposit. Depending on the user's input in responseto the outputs through the display, the exemplary ATM operates to movethrough the appropriate states in a transaction sequence for theparticular type of transaction that the user has selected. Of coursethis approach is exemplary and in other embodiments other approaches maybe used.

As can be appreciated, the at least one processor causes the ATM tooperate in accordance with the transaction sequence and causes signalscorresponding to inputs through the keypad, card reader and/or otherdevices to turn on the encryption function during appropriate states inthe transaction sequence. When the at least one processor in the machinehas the ATM in these particular states, the inputs through the keypad orother device capable of encrypting inputs are encrypted to protect theconfidential information from interception. Of course in exemplaryembodiments in other states in the transaction sequence, the user is notbeing instructed to input confidential information and the at least oneprocessor causes inputs through the keypad to be output to the circuitryof the machine as signals that are unencrypted. Such unencrypted inputsare then transmitted to the at least one processor so that the ATM canthen carry out the appropriate transaction steps.

A potential risk arises if a criminal has electronically accessed themachine in ways that cause a request for input of confidentialinformation to be provided from the machine during a state in thetransaction sequence when the encryption capabilities of the keypad,card reader or other device with encrypting capabilities, are not turnedon. If, for example, the criminal has installed software instructionsthat provides an unauthorized user exit in the transaction sequencewhich causes an output through the display that asks the user tore-enter their PIN number, the user may re-enter their PIN number at atime when the encrypting keypad is not operating to encrypt the inputs.Thus the user's confidential information may be input in the clear andintercepted. Likewise similar unauthorized outputs may request a user toreinsert their card at a time when outputs from the card reader are notbeing encrypted. In still other situations the user may be asked forother types of confidential information such as social security numbers,account numbers, mother's maiden name, etc. all of which might be usedto gain unauthorized access to user's accounts or to accomplish identitytheft.

As may be appreciated some of the ways in which unauthorized outputs canbe caused to be made through an ATM display will not necessarily disruptthe normal operation of the at least one processor or the transactionsequence that occurs responsive to the authorized instructions. Indeedas previously discussed, unauthorized devices can be connected to thedisplay, unauthorized network connections or unauthorized computerexecutable instructions may operate in the at least one processor toperpetrate such unlawful activity. In addition it should be understoodthat such programming, while discussed as being used in connection withproviding outputs through the ATM display, may also be output throughother output devices such as the audio outputs associated with voiceguidance or other similar output devices which provide instructions tousers of the ATM to provide inputs.

To minimize such risks exemplary embodiments may include computerexecutable instructions in the at least one data store, that comprisecharacter recognition software. Further in exemplary embodiments thecomputer executable instructions include software instructions that areoperative to recognize signals that are received by the display on theATM and that cause the display to provide certain outputs. Further theexemplary instructions are operative to determine that the signals beingprovided correspond based on the operation of the character recognitionsoftware, to certain words and/or phrases which suggest that the displayis providing outputs to users that instruct the users to inputconfidential information to the machine.

Thus for example in an exemplary embodiment the at least one processor518 may be in operative connection with appropriate sensors, interfacesor other devices which sense the signals being received by the displayon the ATM. The signals are then analyzed through operation of the atleast one processor to determine if the signals correspond tocharacters, phrases and/or other outputs that instruct a user to inputconfidential information to the machine. For example in exemplaryembodiments, the at least one processor may operate to look for signalswhich correspond to the words personal identification number, PIN,secret number, account identification number or other words and/orphrases (including in exemplary embodiments words and/or phrases inother languages) that are instructing a user to enter their PIN number.

In an exemplary embodiment, upon determining that the display isoutputting such instructions, the at least one processor operates inaccordance with its programming to turn on the encryption functions forinputs through the keypad. In this way upon determining that such anoutput is being provided through the display, the at least one processorassures that the encrypting functions of the keypad are turned on andthe signals being output from the keypad are encrypted. The at least oneprocessor can operate to cause inputs through the keypad to be encrypteduntil the output from the display is determined to no longer ask for auser's confidential information.

In still other embodiments the at least one processor may operateresponsive to determining that a particular type of output requestinguser confidential information is being presented, to determine the statein the particular transaction sequence in which the authorized softwarein the machine is currently operating. Thus for example, the at leastone processor may operate to determine if the current state in thetransaction sequence is the PIN entry state and/or that the at least oneprocessor has already caused the encryption functions of the keypad tobe turned on. In an exemplary embodiment the at least one processor upondetermining that the machine is acting in a normal manner may take nofurther action. However, in circumstances where the at least oneprocessor determines that entry of the customer's PIN is being requestedat a time other than an appropriate state in the transaction sequence,the at least one processor causes the machine to operate to send atleast one message to at least one remote computer indicating an abnormalcondition. This may be accomplished in some embodiments in a manner likethat described in U.S. Pat. No. 6,297,826 the disclosure of which isincorporated herein by reference. Of course in other embodiments otherapproaches may be used.

In the exemplary embodiment the at least one processor may operate inaccordance with its programming to analyze subsequent signals that causeoutputs through the display, and to shut off the encrypting functionswhen the signals received by the display no longer correspond torequests that the customer input confidential information. However, instill other embodiments the at least one processor may be programmed tocause the machine to cease operation either entirely or to cease atleast certain functions, upon the at least one processor determiningthat the display has output a request for confidential information at aninappropriate time during a transaction. Alternatively in otherembodiments other approaches may be taken such as contacting a servicingentity or bank personnel or police authorities to advise of a particularsuspicious condition. In still other embodiments the at least oneprocessor may operate in a manner like that described in U.S. Pat. No.7,147,147 the disclosure of which is incorporated herein by reference,to capture image data and/or other information that may be useful indetermining the cause of the unauthorized ATM operation. Of course theseapproaches are exemplary.

In exemplary embodiments the at least one processor may operatecharacter recognition software therein of the types that arecommercially available. These may include for example software availablefrom Carreker Corporation, A2ia, Parascript. Mitek or other commerciallyavailable software that recognizes characters, words and/or phrases.Such software may be operated to obtain the signals corresponding tothose being sent to and/or received at the display, and convert them tosuitable data for analysis to enable the at least one processor todetermine whether the words, phrases, etc. being looked for are found inthe current output display. Further in some embodiments the at least oneprocessor may be connected through an appropriate interface locateddirectly at or within the housing of the display so that the actualsignals being delivered thereto are monitored. This may be useful forexample in situations where the criminals have included in the machine aseparate processor or other device that delivers signals to the displayin a switched manner. For example in some embodiments it may beappropriate to integrate the signal sensing devices directly into thedisplay to assure that the sensing devices that deliver the signals tothe at least one processor for analysis cannot be bypassed.

In still other embodiments the at least one display may include at leastone processor and data store which includes appropriate programs and theability to provide at least one output back to the processor. Such asystem may provide at least one output signal to the processor in themachine responsive to the signals being received by the display whichcause outputs therefrom. The at least one processor may operate inaccordance with associated programming to assure that the signals beingdelivered to the display at the particular time, correspond to thosesignals that the processor and its associated authorized transactionprograms are causing to be delivered to the display. If the at least onefeedback output signal from the display indicates a variance from whatthe at least one processor determines that the feedback signal ought tobe at the particular time, then the at least one processor may operatein accordance with its programming to take appropriate action. Suchappropriate action may include sending messages, disabling functionsand/or shutting down the ATM. Such feedback output signals may begenerated responsive to encryption of signals being received at thedisplay, which signals can then be compared to the values calculated bythe at least one processor based on the signals it is causing to be sentto the display. Of course other approaches may be used.

In still other embodiments the machine may operate in a manner thatincludes at least one camera adjacent to the display. The cameraoperates to capture images corresponding to screen outputs. This may bedone for example in the manner of the incorporated disclosures. Suchcamera signals may then be analyzed through operation of the at leastone processor, or by a separate authorized processing system, todetermine if the outputs requesting confidential inputs from a user arebeing presented at an inappropriate time in the transaction sequence.Such an approach may be useful in environments where it is not possibleto assure that the signals actually driving the display can be monitoredat all times and/or when there is a risk that a display with antifraudcapabilities has been replaced with a different display. Alternativelyor in addition, such an approach may be useful in situations where acriminal has overlaid an output device on the outside of the displayscreen of the machine. For example a criminal may install a liquidcrystal pane or other display structure on the outside of the authorizedATM display. Such an external display may operate to make it appear thatthe machine is outputting messages to the user, when the messages arebeing generated from the unauthorized overlaid display pane. At othertimes the pane may be operated so as to be transparent. In suchcircumstances the use of systems with imaging devices such as cameraswhich monitor the outputs which the user actually sees, and analyzesthem for requests for confidential information at inappropriate times inthe transaction sequence, or for lack of correspondence with what theauthorized software would cause the output to be, may be useful inhelping to prevent fraud. Of course these approaches are exemplary andin other embodiments other approaches may be used.

As can be appreciated, in some embodiments the at least one processorwhich operates to conduct the analysis for inappropriate outputs, mayinclude processors within the machine such as processors included in thekeypad or other processors such as distributed processors throughout theATM. In still other embodiments as previously discussed, the analysismay be conducted through external processors such as image analysisdevices which operate to capture images or other data from cameras. Instill other embodiments the character recognition software and analysismay be conducted within processors located in tamper resistant devicessuch as the keypad or other devices within the machine that willgenerally cease to operate if an attempt is made to tamper with theiroperation or programming. Of course these approaches are exemplary.

In some exemplary embodiments communications between at least oneprocessor in the machine on the display may be used to assure that thedisplay of the at least one processor are both authorized componentsthat are trusted and are intended for operation in the automated bankingmachine. In exemplary embodiments at least one authorization signal thatis operatively communicated between circuitry associated with thedisplay and the at least one processor helps to assure that at least oneof the components is a trusted component. In the absence of the at leastone authorization signal, the automated banking machine will not carryout at least one transaction function. For example in some embodimentsin the absence of the at least one authorization signal the display maycease to operate to provide any visual outputs. Alternatively in theabsence of the at least one authorization signal the display mayselectively cease to provide certain outputs such as for examplerequests for users to provide confidential information such as a PIN. Instill other embodiments in the absence of the at least one authorizationsignal the display may operate to provide an output such as if the ATMis not 5 operational and is not in service. Of course these approachesare exemplary

In some embodiments the at least one authorization signal may include aplurality of signals that are communicated responsive to the at leastone processor to the circuitry associated with the display and/or fromthe display circuitry to the processor. For example the processor mayoperate to generate a first authorization signal to the display. Thedisplay circuitry may 10 thereafter operate in accordance with computerexecutable instructions stored in connection therewith to cause a secondauthorization signal to be sent to the processor of the associateddisplay driving circuitry which operatively communicates with theprocessor. In some embodiments the authorization signal from the displayto the processor may include a portion that is a function of the firstauthorization signal that is sent to the display circuitry. By having atleast a portion of the second authorization signal reconstituted as afunction of the first signal, there may be greater assurance that thedisplay operating in the machine is an authorized component. Of coursethis approach is merely an example.

In some exemplary embodiments the at least one processor may operate tocause the authorization signal to the display to be a function of thecard data that is read from the card of the customer that is currentlyoperating the machine. This may include for example an encrypted codethat is generally responsive to the card data and which provides aunique data signal to the display circuitry. The display circuitry willthen operate in response to certain computer executable instructions inoperative connection therewith to carry out one or more mathematicalmanipulations based on the authorization sent from the processorincluding the card data and return a second signal to the processor. Theprocessor may then carry out computational functions to verify that theauthorization signal generated by the display circuitry corresponds tothe card data originally sent. In determining such correspondence the atleast one processor may then operate to carry out transaction functionsbased on assurance that the display is being operated as a trustedcomponent. However, in the event that the authorization signal from thedisplay is determined by the at least one processor to be an impropersignal or one that cannot be verified as authorized, the at least oneprocessor may cease to operate the machine to carry out transactions.Alternatively or in addition the at least one processor may cause theautomated banking machine to send at least one message from theautomated banking machine to at least one remote computer to indicatethe possible fraud condition of the ATM. Of course these approaches areexemplary.

In still other embodiments the at least one authorization signal sent bythe at least one processor to the display may include a time signal. Inan exemplary embodiment the at least one processor includes a clockfunction operating therein which is operative to generate datacorresponding to a then current time. Data corresponding to all or aportion of the then current time data may be included in the at leastone authorization signal sent by the processor to the display.Alternatively or in addition the at least one processor, the displayand/or both may have data associated with one or more respective serialnumbers or other numbers associated therewith. The authorization signalscommunicated may be a function of the respective serial numbersassociated with these components. As a result the serial numbers may beused as a basis for assuring that the respective authorized componentsare operating in the machine. Alternatively or in addition otherparameters may be used as the basis for the authorization signals thatare communicated to be sure that the processor and/or the display areauthorized components. Of course in some embodiments combinations ofmultiple parameters may be used.

In still other exemplary embodiments the at least one processor and/orthe circuitry associated with the display may be operative to includeroutines that generate random numbers. For purposes of this disclosure arandom number will be deemed to include any form of random characters orvalues. Such random numbers may be included in the authorization signalsthat are sent by and/or returned from the various components. Forexample in some embodiments a random number generated through operationof the processor may be encrypted through operation of the at least oneprocessor and sent as part of the authorization signal through thecircuitry associated with the display. The display may thereafterprocess the data received including the random number and encrypt it ina manner through operation of one or more processors and computerexecutable instructions associated with the display circuitry. Theauthorization signal returned by the display to the processor of themachine originating the random number will then be analyzed throughoperation of the processor to verify that the return signal is based onthe original random number and has been manipulated in a mannerconsistent with the programming of the circuitry in the authorizeddisplay. Such determination may be used as the basis for continuing theoperation of the at least one processor to carry out transactions. Ofcourse it should be understood that random numbers are but one type ofvalue that may be included in authorization signals.

In still other embodiments each of the at least one processor in themachine on the display circuitry may have an associated respectivepublic/private key pair. In such embodiments the at least one processorin the machine may generate values to be included in an authorizationmessage and encrypt such values using the private key associated withthe at least one processor. The circuitry associated with the displaymay then use the associated public key of the at least one processor todecrypt the message. The ability of the public key associated with theat least one processor to decrypt the message provides assurance thatthe message is sent by the at least one processor.

In the exemplary embodiment the circuitry associated with the displaymay thereafter manipulate or otherwise process all or a portion of thedata received in the message from the at least one processor to generatea further authorization message. In exemplary embodiments this messagemay include one or more portions that are a function of the originalmessage from the at least one processor. The circuitry associated withthe display may then encrypt the authorization message to the at leastone processor using the private key associated with the displaycircuitry. The message is then communicated through the internalcommunications channel of the automated banking machine such as auniversal serial bus connection or other data bus to the at least oneprocessor. The at least one processor may then decrypt the message fromthe display in accordance with its associated programming using thepublic key associated with the display circuitry. The ability of the atleast one processor to decrypt the message using the public key of thedisplay circuitry provides assurance that the message originated fromthe display circuitry. Further the at least one processor may confirmthat the message sent by the display circuitry is based on its originalmessage by comparing or manipulating the data included in theauthorization message to assure that it corresponds with the data thatwas originally sent.

In some embodiments the programming associated with the display and/orthe devices in communication with the processor and driving the displaymay include anti-tampering features. This may include for examplememories that hold data such as public and private key data which areautomatically erased in the event of any attempt to access or manipulatethe data therein that might be consistent if efforts to reverse engineerthe circuitry are made. In still other embodiments such communicationscircuitry and sensitive data may be encapsulated within physicalstructures. Such physical structures may be built to destroy any storedinformation therein in the event an effort is made to open the physicalcasing. Thus for example physical modules associated with the at leastone processor that operate to send messages to the display and/ormodules which are included therein or are connected with the displaycircuitry may be hardened so as to prevent tampering or access thereto.Of course these approaches are exemplary and in other embodiments otherapproaches may be used.

It should be understood that while the exemplary approach has beendiscussed in connection with the display of the machine, otherembodiments may operate using similar principles for other types ofdevices on an ATM which provide outputs and/or receive inputs. Thus forexample the at least one processor in the machine may be programmed tolook for requests to input confidential and/or private customerinformation of the type that can be read from the user's card. This mayinclude for example, asking the customer to re-input a card at aninappropriate time. In exemplary embodiments the at least one processormay operate to turn on an encryption function that can operate in aprocessor associated with the card reader or other device, to avoidinterception of the data as well as to give notification. Further instill other embodiments the at least one processor may include softwareof a type that recognizes verbal outputs. For purposes of thisdisclosure software of the type that recognizes verbal outputs will alsobe called character recognition software. Such software which recognizesverbal outputs may monitor output signals to or through speakers,headphone jacks or other similar output devices on the ATM. The at leastone processor may monitor for the output of words requesting the inputof user confidential information at inappropriate times in thetransaction sequence. This may minimize the risk for example, that ablind user provides their confidential information in response to voiceguidance outputs which are caused to be presented due to criminalmodifications to the ATM.

In addition it should be understood that the features discussed inconnection with FIG. 47 may also be used in conjunction with otherfeatures described herein. This may include for example devices forlimiting unauthorized observation of inputs through the keypad andapproaches for minimizing the risk of unauthorized detection ofconfidential user data.

FIG. 52 shows schematically components of yet another alternativeembodiment of an automated banking machine which is an ATM generallyindicated 592. ATM 592 includes at least one terminal processor 594.Processor 594 is in operative connection with at least one data store596. As in the other embodiments data store 596 includes data as well ascomputer executable instructions that are carried out through operationof the processor to operate the ATM. Of course it should be understoodthat while only one processor and data store are shown, embodiments mayinclude numerous processors and data stores. Further, it should beunderstood that for purposes of this disclosure a reference to aprocessor shall be considered to refer to multiple processors or othercomputer, and a reference to a data store will be construed to encompassmultiple data stores. Also, in some example embodiments, processors thatoperate to control the devices included the ATM may be located in aremote server. This may include for example operating a virtual machinein the remote server which corresponds to the ATM and which causes theoperation of the devices. This may be done for example in the mannerdescribed in U.S. patent application Ser. No. 13/066,272 filed Apr. 11,2011, the disclosure of which is incorporated herein by reference in itsentirety.

Terminal processor 594 is in operative connection with transactionfunction devices of the ATM generally indicated 598. The exemplarytransaction function devices include card reader 600. Card reader 600 isoperative to read data included on user cards. This includes for exampledata corresponding to financial accounts of users of the automatedbanking machine. Such card readers may include magnetic stripe cardreaders, smart card readers that are operative to read data stored on acomputer chip in the card, radio frequency identification (RFID) typereaders, inductance type readers, or other types of readers capable ofreading data included on a card. Further, in other example embodimentscard readers may include devices that have the capability of readingdata typically included on a card from an article such as a mobilephone, personal digital assistant, or other such device that cancommunicate identifying data of the user and/or financial accountwirelessly, such as through Bluetooth, near field communication (NFC),infrared (IR) or other suitable wireless communications methods.

Another exemplary transaction function device is a printer 602. Printer602 may include a receipt printer of the type that provides users withreceipts for transactions conducted at the ATM.

Another exemplary transaction function device in ATM 592 is a cashdispenser 604. Cash dispenser 604 may be of the type previouslydescribed that operates to cause cash such as currency bills that arestored within the ATM to be selectively dispensed and made accessible toa user outside the ATM. The exemplary ATM also includes a depository606. Depository 606 may be of the type that accepts deposits made by auser into the machine. Such deposits may include in some embodimentsdeposited items that are included in deposit envelopes. In otherembodiments the depository may accept items such as cash or checks orother items.

Of course it should be understood that ATM 592 may include other ordifferent types of transaction function devices. These may include forexample different types of input devices, output devices as well asdevices for performing transaction functions of the type desired at theATM.

In the exemplary embodiment ATM 592 includes a touch screen displaymodule 608. In this exemplary embodiment the touch screen display module608 is a structure or assembly of components designed to provide asecure input device through which users can input data which isprotected from being intercepted by unauthorized persons. The exemplaryembodiment of the touch screen display module includes an output pane610 which is alternatively referred to herein as a screen area. Outputpane 610 of the exemplary embodiment comprises a generally transparentpane which is part of a touch sensitive screen. The touch sensitivescreen may be one of several types which can be used to determine therelative location on the screen at which a user makes contact with thescreen using their finger. This may include for example in someembodiments a resistance detecting touch sensitive screen. In otherembodiments the touch sensitive screen may be of the capacitancedetecting type. In still other embodiments the screen may include anacoustic wave detecting type of touch sensitive screen. In still otherembodiments the screen may include a touch sensitive screen connected todisposed force sensors that are operative to determine the location ofuser contact relative to the screen area. In still other embodimentsother types of touch sensitive screens may be used. As can beappreciated other various suitable types of touch sensitive screens maybe used to determine the position of contact made by a user's fingers onthe screen so as to detect when a user touches a selectable visibleoutput that is provided from the display.

An exemplary embodiment of the touch screen display module 608 may alsoinclude a haptic interface system in order to provide tactile feedback.Example haptic touch screens that may be used in exemplary embodimentsmay include the haptic touch screens manufactured by Pacinian Corp. ofSpokane Wash., or Esterline Advanced Input systems of Bellevue Wash., ormay include any other haptic interface system that is operative toprovide tactile feedback with a touch screen.

In an exemplary embodiment, the touch screen display module 608 may becomprised of a haptic touch screen with a manually touchable contactsurface that overlies the screen area of an LCD display screen (or CRTdisplay screen) of the touch screen display module. The haptic touchscreen may be selectively configured to provide tactile feedback (e.g.changes in contour and/or movement in contour which is sensed asvibration) responsive to touches (e.g. finger presses, finger sliding)in designated contact areas on the contact surface of the touch screenthat correspond to virtual buttons (e.g keypad keys and functions keys)or other user interface controls and indicia displayed on the displayscreen under the contact surface of the haptics touch screen. In anexemplary embodiment the selectively contoured contact surface of thehaptics overlay generally extends coextensively with the screen areathrough which visual outputs can be presented. This enables the outputof perceivable tactile outputs and the receipt of tactile inputsgenerally throughout the screen area.

The exemplary embodiment further includes a housing 612. The housing 612of the exemplary embodiment houses internal display module components.These include at least one display module processor 614. The displaymodule processor is in operative connection with at least one moduledata store 616. In the exemplary embodiment the at least one displaymodule data store includes a volatile memory in which at least some ofthe data stored therein is erased in the event of power loss. Theexemplary display module includes a power supply connection so that thevolatile memory of the display module maintains its data when the ATM isturned on. In the exemplary embodiment the housing of the display moduleincludes at least one battery 618. The at least one battery operates toprovide a source of power so as to enable the volatile memory tomaintain data storage even during times when the ATM is turned off orunplugged from an AC power source. In alternative arrangements, othertypes of power sources may be used, such as a capacitor or othersuitable storage or electrical generation device.

In the exemplary embodiment the housing 612 comprises a unitarystructure that is designed to require breakage to access the internalcomponents thereof. This may be done for example by providing apermanently sealed assembly so as to avoid the risk that unauthorizedpersons can gain access to information in the display module data store.For example in an exemplary embodiment the housing includes a pluralityof sensors that are operative to sense an effort to access the interiorarea of the housing. In an exemplary embodiment the sensors may includefrangible electrical conductors 620. The exemplary frangible electricalconductors may be operative to electrically connect the electrical powersource including the battery and the data store. Such conductors mayinclude thin wires, conductive traces or other conductive items thatreadily break when disturbed. Attempts to open the housing may fractureone or more of the electrical conductors resulting in a loss of powerfrom the electrical power source and the battery 618 to the displaymodule data store. Thus in the example embodiment the sensors detectingpossible compromise of the display module, result in the data includedin the display module data store being erased.

Further in exemplary embodiments the sensors may include electricallyconductive material in at least one transparent pane of the touchscreen. This may include for example electrically conductive tracematerial or other material which is operative to provide a sensor thatassures the integrity of the housing. Deformation or breakage to thehousing results in the loss of electrical power to the volatile memoryresulting in erasure of the data in the data store. In some embodimentsfor example the sensors including the electrical conductors may bemolded into components of the display module so as to minimize the riskthat the sensors can be compromised. Of course these approaches areexemplary. Further it should be understood that while in the exemplaryembodiment the approach of maintaining power to the data store is usedto determine efforts to compromise the display module housing, otherapproaches may be used in alternative embodiments. These may include forexample other types of sensors that detect deformation of the housingwhich is indicative of efforts at disassembly or compromise. Likewiseother embodiments may include sensing of changes in gas pressure eitherinto or out of the interior area of the housing so as to detect a breakin the housing indicating a compromised condition. Of course theseapproaches are exemplary and in other embodiments other approaches maybe used.

In the exemplary embodiment the at least one display module data storeis used to store data corresponding to at least one encryption key. Insome exemplary embodiments the at least one encryption key may include asymmetric key such as a key that complies with the Data EncryptionStandard (DES) or other suitable key type. The at least one processor inthe display module may operate in accordance with its programming tocause the display module to output selectable outputs such as the visualrepresentation of a keypad on the display. The visible representation ofthe keypad may include a plurality of keys, each of which may beselected by a user touching the screen where the key appears.

In exemplary embodiments with a haptics touch screen, the moduleprocessor and/or the terminal processor may be operative to configurethe haptic touch screen to provide tactile feedback for the displayedkeys. In some embodiments the at least one module processor may operateresponsive to visual outputs in the screen area to cause changes incontour or vibratory properties of the contact surface in the areaoverlying or otherwise corresponding to the visual output element. Forexample, in the case of a visual representation of a button being outputin a portion of the screen area, the contact surface may change itscontour so as to produce extending ridges, troughs, or other featureswhich define the contours of the visual button. In some embodiments themodule controller may operate to cause contour changes defining multiplevisual buttons being output through the screen. Additionally, some suchembodiments may include the inclusion of contoured indicia inassociation with the contours associated with those buttons or otheroutput visual elements. This may include for example Braille indicia,letters, numbers, or other indicators by which a user can identify thenature of the underlying buttons through finger contact. In still otherembodiments, the contours may be changeable so as to provide vibratoryproperties. In such cases the user's contact with the area associatedwith the underlying image element is detected not only by the changes incontour, but also the oscillation of the contours of the contact surfacewhich is perceived by the user as vibration. Of course these approachesare exemplary, and in other embodiments other approaches may be used.

In some embodiments, the at least one module processor may operate tocause the contours and/or vibratory movement responsive to theappearance of the keys, icons or other image elements output through thescreen area. Thus for example, in some embodiments the at least onemodule processor may be operative to provide outward extending portionsof the contact surface in response to the lines which bound theparticular image. Alternatively or in addition, the at least oneprocessor may be operative to produce contours that correspond tooutward extending portions and recessed portions based on shading orother features that are included in the underlying image element. Thusfor example, the data corresponding to the visual image element may beprocessed through operation of the module processor which producescontours on the contact surface generally corresponding theretoresponsive to associated programming and the data which produces thevisual image element. Alternatively in other embodiments, contours,vibratory properties, or other features may be caused responsive atleast in part to signals such as configuration data sent from theterminal processor to the module processor. The terminal processor mayoperate in accordance with its programming to define templates or otherdata which correspond to the desired contours to be presented on thecontact surface. This may include for example sending a contour map forareas of the contact surface which correspond to the particular visualoutputs that are produced in response to signals being sent from theterminal processor to the module processor. Thus the driving signalssent to the touch screen display module may define the outputs from thedisplay in three dimensions. The at least one processor module mayreceive the data and cause the two dimensional visual outputs throughthe screen area, and cause corresponding contours in the contact surfacethat correspond to represented visual items.

Vibratory properties may in some embodiments be caused responsive tooperation of the module processor in accordance with the programmingthereof. Vibratory properties which may generally correspond to rapidchanges in contour of the contact surface in a contact area where auser's finger is touching the screen, may be caused responsive to thedata which defines the image element. For example, an image whichincludes multiple bounding lines or other indications interpretable asmovement may cause the module processor to operate in accordance withits programming to cause vibration of the contact surface in the area ofthe image element. Alternatively, other types of visual signalindicators such as color, line thickness, shading properties, or otherindicia which can be interpreted by the module processor, may beoperative to cause vibratory properties to be output in association withthat particular image element. In addition, in some alternativeembodiments the terminal processor may operate in accordance with itsprogramming to apply vibratory properties in response to user selection.Thus for example vibratory properties may be output when a user hasprovided a touch input that corresponds to selection of an element.Alternatively, vibratory properties may be outputted upon detection of auser's finger touching or sliding across the contact surface in thecontact area corresponding to the visual element.

In other alternative arrangements, the vibratory properties may beoutput responsive to signals sent from the terminal processor. Aspreviously described, signals sent from the terminal processor mayprovide contour data for the contact surface and may also specify thevibratory properties associated with the area of the contact surface. Asa result, the module processor may operate in accordance with itsprogramming and the data received from the terminal processor inconnection with the display data, to cause vibratory properties inaccordance with pre-defined parameters associated with the particularvisual elements that are caused to be displayed through the displaymodule. Of course these approaches are exemplary, and in otherembodiments other approaches may be used.

In some exemplary embodiments users may provide selections throughmanual contact with the touch screen display module, using differentapproaches depending on the programming of the particular machine. Forexample, in some arrangements the display module may be operative tochange contours of the display responsive to a user moving their fingeracross a particular visually output key or other element. This mayinclude for example the user finding the keys including certaintopographic indicia which identifies the key to the user. Certain keysor other outputs from the contact surface may also include vibratoryproperties, so as to facilitate identification of one or more keys orother elements to the user. Selection of keys or other elements mayinclude for example, the user holding a finger in contact with a contactarea corresponding to an output element for more than a particular timeperiod. This “long press” approach may provide an indication that theuser wishes to select a particular element. The display module operatesin response to this condition to cause the contact with the contact areato be determined by the module processor to be a selection of theunderlying key or element.

Alternatively in other arrangements, an input may be determinedresponsive to a user rapidly touching the contact area corresponding toa visual element a number of times within a time period. Thus forexample, a user contacting the contact area overlying an element twicein rapid succession may result in the module processor determining thosecontacts to be an input corresponding to user selection of that element.Of course it should be understood that various approaches to receivinginputs may be used in various arrangements. In addition, because of theflexibility of the exemplary haptics arrangement, a machine may usedifferent types of approaches to providing tactile outputs and forreceiving inputs. Further it should be understood that numerous types ofvisual elements may be associated with haptics properties. Theseelements can include for example, buttons, arrows, geometric shapes,symbols, characters, letters, numbers and any form or shape that canhave associated contours.

An example of an application for haptics touch screen may includeproviding an image of input keys in the screen area, so that the usercan provide through touch inputs corresponding to their PIN or otherconfidential data. In such embodiments, a keypad may be visually outputthrough the screen. In some exemplary embodiments, the boundaries of thepresented keypad keys may be defined through contours in the contactsurface of the hap tics overlay. The contoured keys may further includecontours which correspond to indicia such as numbers, Braillecharacters, letters, or other touch-perceivable indicators whichidentify the particular visible elements which are being output throughthe display.

To assist in locating a displayed numeric keys of a keypad on the haptictouch screen, in exemplary embodiments, a designated key such as acentral key (e.g. a “5” key) of the keypad may be configured to providea tactile feedback output when initially contacted by a finger, whereasadjacent surrounding keys either do not provide such a tactile feedbackor provide a different tactile feedback. Providing a distinctive hapticfeedback for a designated key (such as a central “5” key) may enable avisually impaired user to slide a finger around the touch screen toidentify the location of the designated key. Once the designated key isfound, the user can use its position to determine the location ofadjacent keys of the keypad. The user may then long press, multipress,or otherwise provide inputs to select one or more of the keys to produceone or more inputs to the machine (e.g. a PIN, amount of value,transaction selection).

In exemplary embodiments, tactile feedback may be outputted responsiveto the detection of a finger pressing or sliding adjacent the edges ofkeys or in the border between keys. For example, the spaces between andaround keypad keys may correspond to a grid that is configured toprovide tactile feedback as the user slides a finger over the spacesbetween and around displayed keys. A visually impaired user may identifythe location of the keypad and the location of individual keys in thekeypad by sliding a finger around the screen to identify the location ofthe grid that defines the keypad.

In example embodiments, the haptic touch screen may be configured toprovide different tactile sensations for different locations (e.g.different displayed keys or other elements) on the screen and fordifferent types of inputs (e.g. sliding a finger or long press of afinger). Such different tactile sensations may be produced by having thehaptic touch screen produce different vibration patterns for thedifferent locations and/or types of inputs. Such different vibrationpatterns may include variations in magnitude, duration, waveform and/orfrequency of the vibration.

For example in one embodiment, each numeric key of a keypad displayed bythe touch screen and touched by a finger of a user, may produce a uniquetactile output in a pattern that can be used to recognize the key beingtouched. Such a pattern for example may correspond to a series of shortand long vibrations based on the Morse Code or other signals for theparticular numeric number associated with the key being touched.Alternatively, the output may be a number of short vibratory outputswhich total a corresponding number associated with the key or othersymbol underlying a user's finger. Alternatively, Braille or othersymbols may be presented. The user could sense the output and select thesymbol by holding a finger in contact with the symbol for a set period.Alternatively, selection might be indicated by a sequence of touches,such as two touches in quick succession or other sequence. Also, itshould be appreciated that in addition to outputting tactile outputs,the processor controlling the haptic touch screen may also causecorresponding audio outputs (beeps, words or tones for example) throughan audio output device associated with the display screen (e.g.headphone jack, loud speakers) to be outputted as well.

Responsive to user input corresponding to one of the selectable outputelements, the exemplary at least one module processor operates inaccordance with its programming to generate encrypted input datacorresponding to the user input. This encrypted input data may begenerated in some embodiments by the display module processor encryptingthe data corresponding to the input using the stored encryption key.Further in some embodiments the input data may be triple encrypted usingthe DES key stored in the at least one data store. The at least oneprocessor 614 of the display module may then operate to cause datacorresponding to the encrypted input data to be communicated to theterminal processor 594. Of course it should be understood that in someembodiments the display module processor may operate to provideencrypted input data corresponding to multiple user inputs provided aspart of a series of inputs from the ATM user. This may include forexample a plurality of inputs provided by the user which correspond tothe user's personal identification number (PIN). Of course this approachis exemplary and in other embodiments other approaches may be used.

In still other embodiments, a display module processor may operate inother modes of operation to facilitate the receipt of inputs from users.For example, the normal operation of an example display module mayinclude providing visual outputs as well as contoured and/or vibratoryoutputs that correspond to the visual elements. Such an arrangement maybe particularly helpful for sighted users of the machine who benefitfrom being able to feel the buttons, arrows, icons, or other elementsthat are presented as visual outputs on the display of the machine.However, in other example embodiments in situations where the terminalis operated by a blind user, the visual elements may not be presented ormay be different from the tactile elements presented, so as to obfuscatethe actual inputs being provided by the blind user. For example as canbe appreciated, the contact surface of the haptics overlay may beoperated to provide contours corresponding to numerous buttons, arrowsor other elements that a user can select, without there being acorresponding underlying visual element. Thus responsive to sensing auser operating a machine in a voice guidance mode, for example, thevisual outputs from the display module may be discontinued responsive tooperation of a processor, and the blind user may make selections basedon the contours corresponding to the tactile elements which exist onlyby virtue of contours of the contact surface. This may have theadvantage that such non-visible tactile elements could be relativelylarge compared with corresponding elements that are presented to sightedusers. This enables a blind user to provide inputs such as PIN numbers,transaction selections and the like through the contact surface of thehaptics overlay without the need for any underlying visual elements.This can be accomplished for example, responsive to signals from theterminal processor that define the contours for the haptics overlay, oralternatively from including particular features within the screen datawhich are not visually perceptible which would be used by the moduleprocessor to produce the 5 contours. Of course these approaches areexemplary.

Alternatively or in addition, in some arrangements the module processormay operate in a mode for blind users where the visual elements whichare output on the screen when receiving input from a blind user have nocorrelation to, or which are even misdescriptive of the selections whichthe blind user is providing through the haptics interface. This couldinclude, for example, visual outputs that differ from or which aredifferent in character from those that the blind user is selectingthrough contact with the contact surface of the haptics overlay. Suchnon-corresponding visual outputs may further reduce the risk ofinterception of any of the inputs provided by such a blind user. Forexample, in such arrangements the terminal processor may operate todetect the connection of headphones or other personal listening devicesby a user, which then causes the display module to operate in such modesto prevent the interception of the user's inputs. Of course theseapproaches are exemplary, and in other embodiments other approaches maybe used.

It should also be understood that in some embodiments the display moduleprocessor may include computer executable instructions includingcommunication verification software or other software of the typespreviously described to assure that it is in operative communicationwith an authorized terminal processor of the ATM. Further in otherexemplary embodiments the display module processor may operate characterrecognition software such that outputs corresponding to requests forinput of sensitive data are recognized to assure that any confidentialinputs by the customer are properly encrypted.

In still other embodiments the at least one display module processor maybe operative to execute instructions which produce the outputs from thedisplay. Thus for example the display module processor and theassociated data store may include computer executable instructions thatproduce the graphics and other output content that is presented by themachine to users. In this way the terminal processor 594 need onlyprovide messages to the touch screen display module which indicates thenature of the current output which the touch screen module is toprovide. This may be useful in avoiding need for the terminal processorto generate the necessary screen output data. This minimizes theprocessing power utilized for this purpose by the terminal processor andalso minimizes the risk that the display may be operated to outputmessages to users that are not appropriate. Of course these approachesare exemplary.

In still other embodiments the data store 616 of the touch screendisplay module may include data corresponding to at least apublic/private asymmetric key pair. Likewise the data store 596associated with the terminal processor may also include datacorresponding to another public/private key pair. The public/private keypairs may each be associated with respective digital certificates. Theterminal processor 594 and the display module processor 614 may operateto communicate messages using the respective certificates and public andprivate key pairs which help to assure that each of the processors is inoperative communication with the other authorized ATM component. Thismay be done in a manner like that previously discussed. For example thepublic key associated with terminal processor 594 may be communicated tothe processor in the touch screen display module and stored in datastore 616. Likewise the public key associated with the display modulemay be communicated and stored in data store 596. By exchanging messageswhich are encrypted with the public keys of the other component, eachprocessor is able to assure that it is in communication with the otherauthorized component and not with a rogue component that has beeninstalled improperly in the machine. Such assurance may be achievedusing techniques that involve the exchange of the certificate data orother secret data or information that helps to assure that eachcomponent is authorized to the other.

In still other embodiments communications between the terminal processor594 and the display module processor 614 may be suitably encrypted so asto minimize the risk of interception. This may include for exampleencrypting communications of data which generally is not required to bekept secret internally within the machine. Such data may include forexample numerical data corresponding to transactions, transactionfunction selection inputs or other information. This may also includethe encryption of messages to the touch screen display module whichcause the output of selectable outputs through the display. This mayinclude encryption of messages that cause the display module to outputthe PIN input or similar outputs. The use of encryption may further helpto assure that the accuracy and secrecy of internal machinecommunications are properly maintained. Further in some embodiments datasuch as customer input data corresponding to a PIN may be encryptedusing the reversible DES encryption key as well as throughcommunications which are encrypted using asymmetric keys. Of course thisapproach is exemplary and in other embodiments other approaches may beused.

In still another arrangement represented schematically in FIG. 53 securecommunications may be further facilitated between the touch screendisplay module and the terminal processor. In this exemplary embodimentsecure communication is facilitated by having the terminal processor andthe touch screen display module connected through at least one secureinput device schematically indicated 622. In the exemplary embodimentthe secure input device includes at least one component having amanually actuatable input device. Further the exemplary secure inputdevice is located within a chest portion 624 of an ATM housing 626. Ascan be appreciated the touch screen display module 608 and the terminalprocessor may both be located within the ATM housing in an upper portion627. The upper portion of the housing of this exemplary embodiment isnot as secure as the chest portion. The chest portion generallycorresponds to a safe with a closable chest door and secure lock. Thechest houses valuable documents such as cash. Thus in this exemplaryembodiment providing for the secure input device 622 to be accessibleonly when the chest portion is open assures that persons that provideinputs thereto are those who are authorized to have access to thevaluables such as cash that are located in the ATM chest.

In the exemplary embodiment the secure input device 622 comprises atleast one processor and at least one data store. The at least oneprocessor is operative to provide for a secure key exchange between thetouch screen display module and the terminal processor or other securecommunications initialization. Thus in the exemplary embodimentactuation of the secure input device operates to cause the establishmentof secure communications between the display module and the terminalprocessor. This may include communications that cause the public keyassociated with the terminal processor to be communicated to the touchscreen display module and stored in the data store therein, and viceversa. This may also include an exchange of certificate, signature orother verification data. This may be done for example in someembodiments to initialize secure communications so that each of thetouch screen display module and terminal processor are recognized by oneanother as authorized machine components. Thus in such embodimentsattempts to replace one or the other of the components will result inthe other of such components determining that it is not in communicationwith an authorized component, and the device will operate in accordancewith its programmed instructions to cease communication of sensitivedata unless the secure input device is again accessed and is used toreinitialize each of the components to the other.

In other embodiments the secure input device may be releasably operablyconnectable with the touch screen display module, the terminalprocessor, or both. Thus for example the secure input device may beoperably connectable with an electrical connector that enablescommunication with the secure input device. In such embodiments thesecure input device may comprise an electronic token or storage devicewhich includes data or program instructions which are operative to causethe terminal processor and/or the display module processor to establishsecure communications. Such secure communications may include theexchange of key data or other data that is operative to assure thesecure communication therebetween. In some embodiments the secure inputdevice may include a smart token or similar device that an authorizedservice person may operably engage with the machine so as to provideinitialization of such secure communications.

In still other embodiments the secure input device may operate inaccordance with its programming to provide monitoring of the securecommunications to help assure that the at least one terminal processorand display module are communicating securely and that there are nosigns of efforts to compromise their operation. This may be done forexample by using multiple signals and encryption techniques that areexchanged between the devices and the secure input device. The secureinput device operates in accordance with its programming to analyze thecommunications and to discontinue normal operation in the event thatconditions corresponding to a possible problem are detected. Further insome embodiments the secure input device may also be in operativeconnection with other transaction function devices so as to disable themfrom operation in the event of a possible detected problem such as asecurity attack. Likewise in still other embodiments the secure inputdevice may also operate to cause the banking machine to givenotifications either locally or remotely of suspected problems. Ofcourse these approaches are exemplary and in other embodiments otherapproaches may be used.

In still other embodiments the processor included in the touch screendisplay module may have programming that enables the touch screendisplay module processor to perform the functions performed by theterminal processor in other embodiments. This includes communicatingwith other transaction function devices in the ATM so as to controltheir operation. Thus for example in some embodiments all of theinstructions necessary for operation of the automated banking machinemay be included in the data store encapsulated within the displaymodule. Efforts to compromise the display module to gain access to anyof the secure programming may result in the loss of operability of theATM. Further as can be appreciated the principles discussed whichprovide secure communications between the touch screen display moduleand the terminal processor may be used in alternative embodiments toachieve secure communications between the touch screen display moduleand the processors operative on individual transaction function devices.

Further in some other exemplary embodiments the touch screen displaymodule may include other input devices that it may be desirable tosecure it from tampering. This may include for example card readercomponents. Thus for example in some embodiments the housing of thetouch screen display module may include a card reader device that isoperative to read data from user cards. This may include for examplecomponents suitable for reading data in a magnetic stripe of the usercard. Alternatively this may include contactless card reading devicessuch as devices that are suitable to read radio frequency or inductancedata signals from cards that are positioned in proximity to the readingdevice. Of course these approaches are exemplary.

By including the card reading capability and user input capabilitywithin a single encapsulated display module some embodiments ofautomated banking machines may reduce the risk of compromise that wouldotherwise be associated with communications between such components ofthe machine. Further encapsulating such components within a singleassembly may further facilitate machine operation and reduce cost andcomplexity in machine design. Of course these approaches are exemplaryand in other embodiments other approaches may be used.

In exemplary embodiments, the terminal processor may be located in acomputer mounted in the same automated banking machine as is thedescribed display module. However, in alternative embodiments, theterminal processor/computer that operates the display module and othercomponents in the machine (e.g. cash dispenser, card reader) maycorrespond to a virtual processor of a virtual machine executing in aremote server. In such embodiments, the display module may include aprocessor and associated circuitry (referred to herein as a portaldevice) configured to securely communicate with and carry out a remoteclient protocol with the virtual machine. Examples of portal devices foruse with automated banking machines and the display devices of automatedbanking machines is shown in U.S. patent application Ser. No. 13/066,272filed April, 2011 which is hereby incorporated by reference herein inits entirety.

In this described example embodiment, the portal device may includeprocessor/controllers adapted to carrying out a remote client protocolsuch as Teradici PC over IP (PCoIP) protocol. Such a PCoOP protocol isoperative to communicate device bus communications corresponding toUniversal Serial Bus (USB) communications and display videocommunications over a TCP/IP network with a remote host processor and/orvirtual machine. The portal device may include USB ports for connectingmachine devices (e.g. cash dispenser, card reader, display module/touchscreen). The portal device may also include video ports for connectingthe display screen of the display module.

In this described embodiment, terminal software such as applications anddevice drivers that operate the automated banking machine, may executein the virtual processor of the remote virtual machine. USB and videocommunications on the remote virtual machine may then be communicated tothe respective devices and display screen in the automated bankingmachine via the portal device.

In an example embodiment of a display module that includes a portaldevice, the display module may include USB ports for connecting devicesin the machine (e.g. cash dispenser, card reader) to the portal device.Internally in the display module, the display screen and touch screenmay be connected to the portal device. Haptics features may be furtheroutput through the contact surface overlying the screen area responsiveto such communication. Also for embodiments of the display module with acard reader, such a card reader may be connected to an internal USBport/header in the display module.

Thus the automated banking machines and systems of the exemplaryembodiments may achieve one or more of the above stated objectives,eliminate difficulties encountered in the use of prior devices andsystems, solve problems and attain the desirable results describedherein.

In the foregoing description certain terms have been used for brevity,clarity and understanding, however no unnecessary limitations are to beimplied therefrom because such terms are for descriptive purposes andare intended to be broadly construed. Moreover, the descriptions andillustrations herein are by way of examples and the invention is notlimited to the details shown and described.

In the following claims any feature described as a means for performinga function shall be construed as encompassing any means capable ofperforming the recited function, and shall not be deemed limited to theparticular means shown in the foregoing description or mere equivalentsthereof.

Having described the features, discoveries and principles of theinvention, the manner in which it is constructed and operated, and theadvantages and useful results attained; the new and useful structures,devices, elements, arrangements, parts, combinations, systems,equipment, operations, methods, processes, and relationships are setforth in the amended claims.

What is claimed is:
 1. A tangible, non-transitory computer readablemedium of instructions with instructions encoded thereon for executionby a processor, and when executed operable to: selectively output visualelements on a display with a touch screen, the visual elements arevisible on the display through a contact surface of the touch screenthat has at least one contact area that is manually touchable; whereinthe visual elements include a first visual element; wherein the firstvisual element is visible through a first contact area; wherein thefirst visual element is selectable by a user of the display throughmanual contact with the first contact area; receive data representativeof a manual touch with the first contact area corresponding to a userselection of the first visual element from the touch screen; wherein thefirst visual element is associated with tactile output; selectivelyproduce tactile output by causing at least one change in contour of thefirst contact area that is independent of any manual contact with thefirst contact area, responsive at least in part to an appearance ofvisual indicia in the first contact area; and selectively producetactile output through the first contact area which allows the user totangibly feel, through manual contact with the first contact area asensation of movement from the first contact area.
 2. The computerreadable medium according to claim 1, wherein the first visual elementcorresponds to a character that is touch selectable during user input ofa personal identification number (PIN), the instructions are furtheroperable to: receive user selection of a PIN character responsive atleast in part to manual touch with the first contact area; wherein thetactile output corresponds to user selection of the PIN character. 3.The computer readable medium according to claim 1 wherein the firstvisual element corresponds to a cash amount, the instructions arefurther operable to receive user selection of the cash amount,responsive at least in part to manual touch with the first contact area.4. The computer readable medium according to claim 1, wherein the firstvisual element corresponds to a transaction type, the instructions arefurther operable to receive user selection of the transaction type,responsive at least in part to manual touch with the first contact area.5. The computer readable medium according to claim 1, the instructionsare further operable to operable to produce tactile output through thefirst contact area by causing vibration in the first contact area. 6.The computer readable medium according to claim 5, the instructions arefurther operable to cause the first contact area to vibrate responsiveat least in part to output of the first visual element in the firstcontact area.
 7. The computer readable medium according to claim 1, theinstructions are further operable to generate encrypted datacorresponding to the user selection of the first visual with anencryption key.
 8. The computer readable medium according to claim 7,wherein the touch screen is mounted on a housing that comprises asensor, the instructions are further operable to cause the encryptionkey to be erased responsive to the sensor detecting opening of thehousing.
 9. The computer readable medium according to claim 1, theinstructions are further operable to produce a tactile output throughrespective different contact areas of the touch screen area.
 10. Atangible, non-transitory computer readable medium with instructionsencoded thereon for execution by a processor, and when executed operableto: output visual elements that are visible through a contact surface onthe touch screen; wherein the contact surface includes a first contactarea; wherein the contact surface includes a changeable contour thatallows the touch screen to selectively provide tactile output throughthe first contact area; cause the touch screen to provide through thefirst contact area prior to manual contact with the first contact areaduring the user session, tactile output that is tangibly indicative of afirst element which is user selectable through manual contact with thefirst contact area; wherein the tactile output provided through thefirst contact area is caused by at least one change in the contour ofthe first contact area; and receive data representative of manualcontact with the first contact area corresponding to a user selection ofthe first element.
 11. The computer readable medium according to claim10, wherein the first element corresponds to a button, wherein thetactile output provided through the first contact area corresponds to atangible representation of the button, and wherein the at least onechange in the contour of the first contact area produces tangibleboundaries of the button.
 12. The computer readable medium according toclaim 10, wherein the visual elements include a first visual element,the instructions are further operable to cause the touch screen toprovide the first visual element through the first contact area prior tomanual contact with the first contact area during the user session;wherein the first visual element is visible through the first contactarea; wherein the first visual element is associated with the tactileoutput provided through the first contact area; and wherein the firstvisual element is visually indicative of the button.
 13. The computerreadable medium according to claim 10, the instructions are furtheroperable to cause the touch screen to temporarily provide vibration inthe first contact area, responsive at least in part to receiving datarepresentative of the user input indicative of manual contact with thefirst contact area.
 14. A tangible, non-transitory computer readablemedium comprising computer readable instructions for execution by aprocessor, and when executed operable to: output visual elements thatare visible through a contact surface of a touch screen associated witha touch screen display; wherein the contact surface includes a firstcontact area, wherein the contact surface includes a changeable contourthat allows the touch screen to selectively provide tactile outputthrough the first contact area; cause the first contact area, the touchscreen to temporarily provide tactile output through the first contactarea independent of any manual contact with the first contact area;wherein the tactile output provided through the first contact area iscaused by at least one change in the contour of the first contact area;wherein the tactile output provided through the first contact area istangibly indicative of a first element which is user selectable throughmanual contact with the first contact area; and receive datarepresentative of manual contact with the first contact area, whichcorresponds to a user selection of the first element.
 15. The computerreadable medium according to claim 14 wherein the first elementcorresponds to a button; wherein the tactile output provided through thefirst contact area corresponds to a tangible representation of thebutton, and wherein the at least one change in the contour of the firstcontact area produces tangible boundaries of the button.
 16. Thecomputer readable medium according to claim 15 wherein the visualelements include a first visual element, wherein the instructions arefurther operable to cause, independent of any manual contact with thefirst contact area, the touch screen to provide the first visual elementthrough the first contact area; wherein the first visual element isvisible through the first contact area; wherein the first visual elementis associated with the tactile output provided through the first contactarea; and wherein the first visual element is visually indicative of thebutton.
 17. The computer readable medium according to claim 14 whereinthe instructions are further operable to cause the touch screen totemporarily provide vibration in the first contact area, responsive atleast in part to receiving data representative of the user input throughthe at least one manual contact with the first contact area.
 18. Thecomputer readable medium according to claim 14 wherein the first elementcorresponds to a character that is touch selectable during user input ofa personal identification number (PIN), wherein the at instructions arefurther operable to receive data representative of a user selection of aPIN character responsive at least in part to manual contact with thefirst contact area.
 19. The computer readable medium according to claim14 wherein the first element corresponds to a cash amount that is touchselectable during user input of cash amount data, wherein the atinstructions are further operable to receive user selection of the cashamount responsive at least in part to manual contact with the firstcontact area.
 20. The computer readable medium according to claim 14wherein the first element corresponds to a transaction type that istouch selectable during user input of transaction type data, wherein theinstructions are further operable to receive data representative of auser selection of the transaction type responsive at least in part tomanual contact with the first contact area.